Memoirs of
Museum Victoria

Volume 62 Numbers 1 and 2 31 December 2005

Front cover Top left: a new species of seastar from Mauritius, Ailsastra eleaumei, described by P. Mark
O’Loughlin and Francis W.E. Rowe. Top centre: an earbone of a fossil dolphin of the family Delphinidae from
the Pliocene Whalers Bluff Formation, Portland, Victoria, described by Erich M. G. Fitzgerald. Bottom: a new
species of fossil sea urchin, Spatagobrissus dermodyorum, described by Francis Holmes from the early
Middle Miocene Glenforslan Formation near Blanchetown, South Australia. Back cover: male reproductive
organs of a new species of millipede, Lissodesmus dignomontis , from Tasmania, described by Robert
Mesibov.

Memoirs of Museum Victoria 62(1): 1-66 (2005)

ISSN 1447-2546 (Print) 1447-2554 (On-line)
http://www.museum.vic.gov.au/memoirs/index.asp

Homalonotid trilobites from the Silurian and Lower Devonian of south-eastern
Australia and New Zealand (Arthropoda: Trilobita: Homalonotidae)

Andrew C. Sandford

Department of Earth Sciences, University of Melbourne, Victoria 3010, Australia (andrewsandford@hotmail.com)

Abstract Sandford, A.C. 2005. Homalonotid trilobites from the Silurian and Lower Devonian of south-eastern Australia and New

Zealand (Arthropoda: Trilobita: Homalonotidae). Memoirs of Museum Victoria 62(1): 1-66.

Trilobites belonging to the Homalonotidae are well represented in the Silurian and Early Devonian of south-eastern
Australia and New Zealand, and are a significant component of the family world- wide. Their description provides an
opportunity to review relationships between species and higher order taxa. A new genus Wenndorfia and two new sub-
genera Trimerus ( Ramiotis ) and T. ( Edgillia ) are described, and revised diagnoses are given for Trimerus, Homalonotus,
Dipleura , Digonus and Parahomalonotus. Species described or redescribed from central Victoria include Homalonotus
williamsi sp. nov., H. talenti sp. nov., Dipleura garratti sp. nov., Digonus wenndorfi sp. nov., Trimerus ( Trimerus ) vomer
(Chapman, 1912), T. (T.) harrisoni (McCoy, 1876), T. {Edgillia) kinglakensis (Gill, 1949), T. (E.) jelli sp. nov.,
T. { Ramiotis ) rickardsi sp. nov., T. (R.) tomczykowa sp. nov., T. (R.) otisi sp. nov., T. (R.) thomasi sp. nov. and Wenndorfia
lilydalensis (Gill, 1949). Tasmanian species described include T. (R.) iani sp. nov., Brongniartellal sp. and D. zeehan-
ensis (Gill, 1949). Wenndorfia expansa (Hector, 1876) (= H. {Burmeisteria) huttoni Allan, 1935, = D. margaritifer
Wenndorf, 1990) from New Zealand is redescribed.

Complex relationships between trilobite faunal composition and taphonomy demonstrate that homalonotid
assemblages are inadequately described by the biofacies concept. A recurrent relationship can be recognised between
homalonotid-dominated low diversity assemblages and high diversity assemblages in relatively shallower-water facies
in which homalonotids are minor faunal elements. These paired assemblages occur variously along a bathymetric
gradient that reflects specific environmental tolerances, and precludes the definition of discrete assemblage-facies
associations.

Keywords Trilobita, Homalonotidae, Silurian, Devonian, Australia, New Zealand, systematics, biofacies

Table of Contents

Introduction 1

Geological Setting 2

Taphonomy and biofacies 6

Systematic palaeontology 12

Homalonotus 14

Homalonotus talenti sp. nov 16

Homalonotus williamsi sp. nov 19

Brongniartella sp 21

Digonus 21

Digonus wenndorfi sp. nov 23

Digonus zeehanensis (Gill, 1949) 28

Dipleura 28

Dipleura garratti sp. nov 30

Trimerus 33

Trimerus (Trimerus) harrisoni (McCoy, 1876) 34

Trimerus ( Trimerus ) vomer (Chapman, 1912) 35

Trimerus (Edgillia) subgen. nov 38

Trimerus (Edgillia) kinglakensis (Gill, 1949) 39

Trimerus (Edgillia) jelli sp. nov 41

Trimerus (Ramiotis) subgen. nov 43

Trimerus (Ramiotis) rickardsi sp. nov 44

Trimerus (Ramiotis) iani sp. nov 47

Trimerus (Ramiotis) otisi sp. nov 49

Trimerus (Ramiotis) thomasi sp. nov 53

Trimerus (Ramiotis) tomczykowae sp. nov 54

Wenndorfia gen. nov 55

Wenndorfia expansa (Hector, 1876) 56

Wenndorfia lilydalensis (Gill, 1949) 60

Acknowledgements 62

References 63

Introduction

Homalonotid trilobites were first recorded from south-eastern
Australia and New Zealand as early as the 1860s, and eight
species have been described subsequently including
Homalonotus expansus Hector, 1876, H. harrisoni McCoy,
1876, H. (Burmeisteria) huttoni Allan, 1935, Trimerus lily-
dalensis Gill, 1949, H. vomer Chapman, 1912, T. kinglakensis
Gill, 1949, T. zeehanensis Gill, 1949 and Digonus margaritifer

2

Andrew C. Sandford

Wenndorf, 1990. The relationships of these taxa have been
poorly understood, as most of them were inadequately
described from limited populations and/or poorly preserved or
incomplete individuals. Museum Victoria houses a large col-
lection of homalonotid specimens from Australasia which not
only permits the redescription of these species, but also the
description of many new species.

Both in taxonomic diversity and abundance the homalonotid
fauna of south-eastern Australia is of world- wide significance.
It is undoubtedly the best preserved representation of the
family for the Llandovery to Lochkovian interval, representing
about one-third of species so far described (Table 1). Three
Llandovery species bring to eight the total number of homa-
lonotids recorded from the interval, with two of them being
among the three best known taxa. Seven Victorian Ludlow
species bring to 15 the total number of homalonotids recorded
from that interval. Similarly, four Lochkovian species make up
one-quarter of the total number of homalonotids recorded from
that interval. The species assigned below to Homalonotus are
two of the total of five assigned to that genus globally, whilst
the nine species assigned below to Trimerus represent almost
half of the species assigned to that genus. A species assigned to
Dipleura is the earliest known representative of the genus,
and two species assigned to Digonus are among the earliest
representatives of that genus.

Historically, the systematics of the Homalonotidae has been
heavily weighted towards the classification of European and
North American species that represent about two-thirds the
total number of species so far described. This trend persists in
the two most recent taxonomic revisions accompanying the
description of north European faunas (Tomczykowa, 1975;
Wenndorf, 1990). In contrast and with the exception of
Burmeisteria, species from Asia, North Africa and the southern
hemisphere have been accommodated in taxa established for
the European and North American faunas. However, problems
arise with the uncritical application of generic concepts estab-
lished for European and North American faunas to the classifi-
cation of southern hemisphere homalonotids, and are manifest
in the nomenclatural changes suffered by some of the few well
documented species. Homalonotus clarkei Kozlowski, 1923
from the Devonian of Brazil has been variably assigned to
Digonus (Wolfart et al., 1968), Trimerus! (Tomczykowa,
1975), Burmeisteria (Cooper, 1982), and Dipleura (Wenndorf,
1990). Similarly, B. ( Digonus ) accraensis Saul, 1967 from the
Devonian of Ghana has been variably assigned to Trimerus
(Tomczykowa, 1975), Burmeisteria (Cooper, 1982) and
Dipleural (Wenndorf, 1990). The comprehensive redescription
of the Australian homalonotid fauna in this work documents a
morphological diversity that demands a more critical usage of
established generic concepts. Revised diagnoses are given in
this work for Homalonotus, Digonus, Parahomalonotus,
Dipleura and Trimerus to accommodate the morphological
diversity of the Australasian fauna.

The Australasian fauna provides new perspectives on the
relationships between species. Trimerus is well represented in
the Australian fauna with nine species assigned to the genus.
The relationships between these and other species of the genus
are formalised in the description of the new subgenera Ramiotis

and Edgillia. T. lilydalensis from Victoria shows closest
relationships to European species previously assigned to
Parahomalonotus. The new genus Wenndorfia is erected
to accommodate T. lilydalensis and these closely related taxa,
and the concept of Parahomalonotus is revised and restricted to
those species close to the type. Reassignment of species
to these groups (Table 1) reflects these revised concepts.

The Silurian and to a lesser extent the Early Devonian are
generally considered periods of cosmopolitanism, and this is
reflected in the widespread distribution of species groups and
higher taxa. Although restricted to the late Wenlock-early
Ludlow, Trimerus ( Trimerus ) is represented in North America,
South America, Europe and Australia, with T. (T.) vomer from
Victoria and T. (T.) johannis Salter, 1865 from England
defining a distinct trans-global species group. Wenndorfia lily-
dalensis from the early Pragian of Victoria is closest to poorly
known species from the late Lochkovian of Europe. The mor-
phological diversity present in the Australian fauna is more a
reflection of the age of the fauna rather than its palaeogeo-
graphic setting. Most of the Australian species are from the
Llandovery, Ludlow and Lochkovian intervals in which many
of the species documented from elsewhere are poorly under-
stood and have had little influence on systematics. Trimerus
( Edgillia ) is erected for a distinct group of globally distributed
Pndolf-early Lochkovian species typified by T. (E.) king-
lakensis from central Victoria but otherwise very poorly repre-
sented in the fossil record. Similarly, T. ( Ramiotis ) is erected for
a widespread group of Llandovery-Ludlow species poorly
represented in the fossil record outside Australia. Siluro-
Devonian homalonotid groups not represented in Australia and
New Zealand include Parahomalonotus, Burmeisteria,
Burmeisterella, Scabrella and Arduenella .

Geological Setting

In central Victoria, trilobite-bearing Silurian to Lower
Devonian marine sedimentary rocks of the Murrundindi
Supergroup crop out in a structurally bound area known as the
Melbourne Zone (VandenBerg et al., 2000). Lithologies are
predominantly interbedded mudstones, siltstones and fine to
medium-grained sandstones, although coarse sandstones and
conglomerates occur at various horizons. Carbonates, known
only from the Lower Devonian in the central and eastern areas
of the Melbourne Zone, are poorly represented and occur as
isolated, discrete limestone bodies.

Homalonotids are restricted in distribution to non-carbonate
sequences between Melbourne, Heathcote and Lilydale in the
western and central areas of the Melbourne Zone (Fig. 1). The
lithostratigraphy of these homalonotid-bearing sequences has
been variously described. The definition, correlation and age of
the various trilobite-bearing lithostratigraphic units described
from these sequences has been reviewed by Rickards and
Sandford (1998) and Sandford (2000, 2002, 2003, 2004).
Stratigraphic nomenclature for the Llandovery to early Ludlow
sequence used in this work (Fig. 2) follows Rickards and
Sandford (1998: fig. 2) and Sandford (2000: fig. 2), and that for
the overlying Ludlow to Pragian sequences follows Sandford
(2002, fig. 2). Homalonotids first appear in the latest

Table 1. Distribution of Silurian and Devonian homalonotid trilobites. Australian species are underlined.

Homalonotid trilobites from the Silurian and Lower Devonian

3

4

Andrew C. Sandford

Figure 1. Distribution of fossil marine faunas with homalonotids in south eastern Australia and New Zealand. Localities for the Heathcote,
Springfield- Kinglake West and Lily dale areas are detailed in Figures 8, 11 and 23.

LATE LLANDOVERY WENLOCK LUDLOW PRfDOLI

Homalonotid trilobites from the Silurian and Lower Devonian

5

EMStAN

PRAGIAN

LOCHKOVIAN

LUDFORDIAN

GORSTIAN

HOMERIAN

SHEINWOODIAN

TELYCHIAN

graptolite,conodont
and brachiopod biozones
recognised in Victoria

ucATum-rc SPRINGFIELD- MELBOURNE-
HtAIHLUIt kinglakewest ULYDALE

pirenae

sulcatus

nilssoni

iudensis

nassa/parvus

testis/

lundgteni

griestonieftsis

Cfispus

turriculatus

Boucotia

loyolensis-

Boucotia

australis

Boucotia

jartaea

Hotopormello

pientlensis

Aegiria

thomasi

TOP NOT EXPOSED

PUCKAPUNVAL

FORMATION

III

MCIVOR

FORMATION

MELBOURNE

FORMATION

VAN YEAN
FORMATION

WAPENTAKE

FORMATION

COSTERFIELD SLT
BASE NOT EXPOSED-

TOP NOT EXPOSED

NORTON

GULLY

SANDSTONE

WILSON

CREEK

SHALE

PUCKAPUNVAL

FORMATION

Cullin' Qu.vry 55 M™

HUMEVALE

SILTSTONE

MELBOURNE

FORMATION

YANYEAN

FORMATION

BYLANDS
SILTSTONE
BASE NOT EXPOSED

AAAAAAAA

LILYDALE

LIMESTONE

Verirtgbeig 5 S Mjfm

HUMEVALE

SILTSTONE

CHRISTMAS

HILLS

FORMATION

MELBOURNE

FORMATION

YANYEAN

FORMATION

Mullum Mullum
Sandstone Member

ANDERSON

CREEK

FORMATION

WarrandyiiCcjl Mem

BASE NOT EXPOSED -J

REEF TON
GROUP

BATON

RIVER

GROUP

W, lilydolertsis

| T(E.)jeili
|d. wenndorfi

T. (E.) kingiakensis

BELL SHALE

FLORENCE

QUARTZITE

ZEEHAN

ci r.mjodsi

y I | T(R.) thomasi
jHiYi/tonosc

D. garratti

| Z(T.) harrisoni

I 7 ™.!

I T?spp.

| T.(R-) tomczykowae

C H I NTI N F M N | T.fRJ rickordsi

TZRJfanl

B.sp.

TIGER RANGE

RICHEA SLT

SPRINGFIELD

SANDSTONE

CENTRAL VICTORIA
DARRAWEIT GUI M PROVINCE

CELL

QUARTZITE

TASMANIA
NEW ZEALAND

Figure 2. Stratigraphic distribution of homalonotids in the Heathcote, Springfield-Kinglake West and Lilydale sequences in central Victoria, and
in Tasmania and New Zealand. Stratigraphic scheme for the Llandovery-Ludlow of central Victoria follows Rickards and Sandford (1998), and
for the Ludlow-Lochkovian follows Sandford (2002).

D.zeehanensis W.expansa

6

Andrew C. Sandford

Llandovery Chintin Formation at Springfield and occur at
various horizons in the overlying sequences, ranging high in
the Mt Ida Formation at Heathcote in strata considered to be
late Lochkovian in age, and ranging up to the top of the
Humevale Formation at Lily dale in strata considered to be early
Pragian in age. Homalonotids do not occur in the various
Lochkovian-Pragian trilobite faunas from the western areas of
the Melbourne Zone, east of Lilydale. Silurian-Early Devonian
sequences occur widely in Tasmania, but homalonotids are
known only from the south-western areas, in the Llandovery
Richea Siltstone northwest of Maydena and in the Lochkovian
Bell Shale at Zeehan. On the south island of New Zealand,
homalonotid trilobites are known from the Lochkovian-
?Pragian Baton Formation, Baton River and from the ?Pragian-
Emsian Lankey Limestone at Reefton.

Silurian and Devonian trilobite faunas occur widely across
the eastern states of Australia, and the restricted distribution of
homalonotids to the south-western areas of the Melbourne
Zone and to south-western Tasmania is noteworthy. Acastid
trilobites are similarly distributed, whereas the distribution of
harpetid trilobites complements that of the homalonotids and
acastids, ranging from eastern Victoria to northern Queensland.
The limited distribution of homalonotids in eastern Australia
parallels their distribution in Europe across the Rheinischen-
Bohemischen facies boundary. The barrier to dispersal in east-
ern Australia is not apparent for other trilobites, particularly the
phacopids and the calymenids. Echidnops, the Ananaspis
typhlagogus (Opik, 1953) species group and individual species
such as Sthenarocalymene sp. A of Chatterton, Johnson and
Campbell, 1979 are represented both in central Victoria and
New South Wales. It is currently held that the sequences of the
Melbourne Zone were deposited on a low gradient shelf on the
eastern margin of the Australian continental plate. In contrast,
the sequences in eastern Victoria, New South Wales and
Queensland were deposited on off-shore island-arc platforms
many hundreds of kilometres from the mainland (Foster et al.,
1999). It seems that although many trilobite groups were able
to establish themselves in these settings, homalonotids (and
acastids) were unsuccessful in dispersing from the continental
margin. Isolation of the homalonotids can be attributed to pref-
erences for continental margin environments.

Taphonomy and biofacies

The homalonotid-bearing trilobite faunas from the Silurian and
Lower Devonian of central Victoria are quite variable in taxo-
nomic composition and relative abundance of species, taphon-
omy, associated lithofacies and associated non-trilobite faunal
elements. Several faunas can be assigned to homalonotid-
dominated biofacies including the Homalonotid Association
(Mikulic, 1999), the Trimerus delphinocephalus-Dalmanites
limulurus Association (Mikulic, 1999) and the Digonus
Biofacies (Fortey and Owens, 1997). Other faunas resemble the
Acaste-Trimerus Association (Thomas, 1979).

Mikulic (1999) emphasised trilobite elements of Boucot’s
(1975) shallow water ‘Homalonotid-P/ectorcotns BA-1
Community’ in defining the Homalonotid Association. Mikulic
nominated the low diversity/monospecific Ludlow assemblages

dominated by Homalonotus dawsoni Hall, 1860 of the
Stonehouse Formation, Arasaig, Canada as typical. The bio-
facies is associated with coarse- to fine-grained siliciclastics of
nearshore environments and a taphonomy dominated by dis-
articulated exoskeletal elements. Mikulic assigned faunas
ranging worldwide from the Caradoc through to the Givetian to
the Homalonotid Association. Taxa commonly associated with
this assemblage include Acaste, Acastella, Encrinurus,
Scotiella, Dalmanites and calymenids. The Homalonotid
Association can be recognised in the Upper Silurian-Lower
Devonian sequences at Heathcote in central Victoria, repre-
sented by populations of Homalonotus talenti sp. nov.,
Trimerus ( Ramiotis ) thomasi sp. nov. and Digonus wenndorfi
sp. nov. at successive horizons. Most typical is the mono-
specific assemblage at the type locality of H. talenti (PL6650,
Heathcote). The population is preserved in thick-bedded coarse
sandstones of the Mclvor Formation and is represented pre-
dominantly (94%) by isolated sclerites. At its type locality
(PL2203, Heathcote), the population of D. wenndorfi is repre-
sented entirely by isolated sclerites. The species occurs in
medium to coarse sandstones of the Mt Ida Formation in asso-
ciation with rare Acastella sp. and an abundance of very large
bivalves and brachiopods (Fig. 3). The latter indicate alignment
of the fauna to the ‘big-shell community’ of Boucot and
Johnson (1967), later formally designated benthic assemblage
BA-1 (Boucot, 1975) and interpreted to be a very shallow-
water community. The D. wenndorfi fauna at PL2203 can also
be assigned to the Digonus Biofacies of Fortey and Owens
(1997). The Digonus Biofacies was recognised as the shallow-
est in a succession of depth-related trilobite associations of
Early Devonian shelf environments, with deeper associations
named after their characteristic key taxa Scutellum,
Lepidoproetus, Odontochile and Otarion. Although Fortey and
Owens did not provide any description of these associations,
their scheme follows Chlupac’s (1983, 1987) depth-related
succession of lithofacies and trilobite associations described
from the Czech sequences as Major Assemblage Groups I-V.
The association of Digonus, Acastella and an abundance of
bivalves at PL2203 also resembles Thomas’ (1979) Trimerus-
Acaste Association, described from shallow water facies of the
British Wenlock. The Trimerus -Acaste Association can be
regarded as the Silurian equivalent of the Devonian Digonus
Biofacies, both considered here as synonyms of the
Homalonotid Association.

Low diversity trilobite faunas with species of Trimerus and
Dalmanites (or Odontochile) as the two dominant taxa occur at
successive horizons in deeper-water sequences south of
Heathcote. An earliest Ludlow fauna from PL386, Wandong is
dominated by an association of D. wandongensis Gill, 1948 and
T. (T.) vomer. The fauna is preserved in siltstones as isolated
sclerites and partly disarticulated exoskeletons, some of which
represent moult assemblages and indicate a depositional envi-
ronment below storm wave base (Sandford, in press). A late
Ludlow fauna from PL 1898, Eden Park is similarly preserved,
dominated by T. ( Ramiotis ) otisi sp. nov. (relative abundance
96%) with rare Odontochile formosa Gill, 1948 (relative abun-
dance 4%). A late Lochkovian fauna from the upper massive
siltstone beds at Middendorps Quarry (PL252, Kinglake West)

Homalonotid trilobites from the Silurian and Lower Devonian

7

Figure 3. Sandstone slab from PL2204 (Thomas’ F4, Parish of Dargile), Heathcote with bedding plane showing numerous isolated pygidia and
cranidia of Digonus wenndorfi in various orientations and with large bivalves and brachiopods indicative of Boucot and Johnson’s (1967) ‘big
shell’ community.

is dominated by T. ( Edgillia ) kinglakensis (relative abundance
99%) with rare O. formosa. These assemblages can be assigned
to the T. delphinocephalus-D. limulurus Association, typified
by a trilobite fauna dominated by these taxa from the Wenlock
Rochester Shale, USA. Mikulic (1999) interpreted the commu-
nity as a deeper-water facies association, preserved as disartic-
ulated exoskeletons in fine-grained, deep water/low energy sili-
ciclastics and aligned with BA 4 and BA 5 communities, Brett’s
(1983) Amphistrophia-Dalmanites Community in particular.
Mikulic (1999) tentatively assigned assemblages occurring in
shallower facies (BA3) to the T. delphinocephalus-D. limulurus
Association. Equivalent shallower assemblages in central
Victoria include the O. formosa- dominated fauna from the
lower coquinal siltstones and sandstones at Middendorps
Quarry, in which T. (E.) kinglakensis is rarer.

At a number of localities in the uppermost Humevale
Siltstone at Lilydale Wenndorfia lilydalensis occurs with
Acastella frontosa Shergold, 1968, often as dominant elements
of the fauna. These faunas resemble Thomas’ (1979) Trimerus-
Acaste Association, although the facies at Lilydale suggest a
deeper-water setting. Another acastid, Acaste lokii Edgecombe,

1993, occurs lower in the Humevale Siltstone in the Lily-
dale area, its stratigraphic range overlapping with that of
W. lilydalensis, but the two species never occur together.

Despite the recognition of homalonotid biofacies at several
localities, the homalonotid faunas of south-eastern Australia are
otherwise inadequately described by the biofacies concept.
Patterns can be recognised demonstrating more complex
relationships between homalonotid relative abundance, faunal
diversity, taphonomy and lithofacies. A skewed inverse
relationship between relative abundance and faunal diversity
can be demonstrated, with lower diversity trilobite associations
having homalonotids proportionally over-represented, and
higher diversity associations with homalonotids under-
represented. In the higher diversity faunas, dalmanitids or
proetids are frequently the dominant taxon, although acastids,
phacopids and rarely odontopleurids may also dominate. The
relationships between taxonomic diversity and homalonotid
relative abundance is best expressed graphically (Fig. 4).

Several species from central Victoria including Digonus
wenndorfi, Trimerus ( Edgillia ) kinglakensis, T. ( Ramiotis )
otisi and Wenndorfia lilydalensis are known from both low

Andrew C. Sandford

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TAXONOMIC DIVERSITY

Figure 4. Relationship between trilobite faunal diversity and homalonotid relative abundance. Only homalonotid-bearing faunas represented by
more than 10 specimens are plotted. The curve connects plot-points of hypothetical faunas where species are represented in equal proportional
relative abundance. Homalonotid faunas cluster in two groups, lower diversity faunas with homalonotids over-represented (above the line) and
high diversity faunas with homalonotids generally under-represented (below the line).

diversity, homalonotid-dominated assemblages and high
diversity assemblages in which homalonotids are under-repre-
sented. From these occurrences, a pattern emerges revealing a
relationship between trilobite assemblage composition, taphon-
omy and lithofacies (Table 2). This relationship is best illus-
trated in the distribution of T. (E.) kinglakensis in the upper
massive siltstones and the lower bedded coquinal siltstones and
sandstones at Middendorps Quarry, where a marked contrast in
facies accompanies differences in faunal composition. In the
upper beds T. ( E .) kinglakensis is extremely dominant (relative
abundance 99%) in a low-diversity assemblage accompanied
by rare Echidnops hollowayi Sandford, 2002 and Odontochile
formosa. Individuals are preserved predominantly as partly
articulated and frequently incomplete exoskeletons or other-
wise as isolated pygidia. Despite the exceptionally high pro-
portion of partly articulated exoskeletons, complete fully artic-
ulated exoskeletons are absent. Many of the partly articulated

exoskeletons can be interpreted as moult assemblages, pre-
served in typical phacopid fashion with the cephalon displaced,
often inverted and/or lying underneath the thoracopygon (Figs
5 A, 5D). Partly-articulated thoraces can be interpreted as ele-
ments of moult assemblages scattered by the movements of the
animal during the exuvial process. Indeed, it is probable that
the whole population of T. (E.) kinglakensis in the massive silt-
stones (including the isolated cephala and pygidia) are derived
from exuviae rather than dead individuals.

Well bedded, siltstones and graded sandstones with poorly
sorted, bioclastic basal coquinal lags underlie the siltstones at
Middendorps Quarry and yield a much more abundant and
diverse benthic fauna. By world standards ten taxa is low diver-
sity for an Early Devonian trilobite assemblage, but for central
Victoria this is one of the most diverse. The assemblage is dom-
inated by Lepidoproetus sp. and Odontochile formosa with a
combined relative abundance of 64%. Trimerus (Edgillia)

Homalonotid trilobites from the Silurian and Lower Devonian

9

Table 2. Relationships between lithology, relative abundance and taphonomy for Trimerus (Edgillia) kinglakensis, Trimerus ( Ramiotis ) otisi and
Wenndorfia lilydalensis. Populations of the latter species in the Eden Park and Humevale siltstones are taken as a whole.

Trimerus (Edgillia)
kinglakensis

Humevale Formation
PL252 (type locality)

Trimerus (Ramiotis) otisi

Eden Park Formation

Wenndorfia lilydalensis

Humevale Formation

LITHOLOGY

siltstone

coquina

siltstone

coquina

siltstone

(Clonbinane
Sandstone
Member:
PL300, PL6642)

coquina

(PL 1804)

TOTAL specimens

286

15

132

8

58

1

RELATIVE ABUNDANCE

99%

15%

96%

24%

26%

2%

TAPHONOMY

complete dorsal exoskeleton

0

40%

1%

36%

0

100%

cephalothorax

<1%

0

1.5%

13%

2%

0

cephalon with displaced thoracopygon

12%

0

2%

0

2%

0

cephalon with displaced thorax

10%

0

1.5%

0

0

0

cephalon with displaced thorax and

displaced pygidium

1%

0

0

0

0

0

cephalon

11%

0

11%

0

17%

0

isolated cranidium

<1%

0

17%

0

12%

0

isolated librigena

0

0

2%

0

5%

0

isolated hypostome

0

0

1%

0

0

0

articulated/partly articulated thorax

9%

0

6%

0

0

0

loosely disarticulated thorax

<1%

0

0

0

0

0

isolated thoracic segment

0

0

2%

13%

21%

0

partly disarticulated thorax, displaced pygidium

3%

0

0

0

0

0

complete/partly complete thoracopygon

36%

0

7%

13%

0

0

isolated pygidium

15%

60%

48%

25%

41%

0

articulated/partly articulated specimens

84%

40%

70%

75%

21%

100%

TAPHOFACIES

TIV

Till

TIV

Till

TIV

Till

kinglakensis is a minor faunal element (relative abundance
<3%). In further contrast to its representation in the overlying
siltstones, the population of T. (E.) kinglakensis in the coquinas
has a high proportion (13%) of complete, fully articulated
exoskeletons. Populations of other species in these beds also
have a high proportion of complete exoskeletons, including
Lepidoproetus sp. (42%), Maurotarion sp. (33%), Echidnops
hollowayi (21%), Leonaspis sp. (11%) and Dicranurus king-
lakensis Gill, 1947 (6%).

Similar relationships between faunal composition and
taphonomy can be demonstrated for Trimerus ( Ramiotis ) otisi
and Wenndorfia lilydalensis. The single known complete
exoskeleton of W. lilydalensis from PL 1804, Coldstream is
exceptional in several respects. It occurs in a bioclastic
coquinal lag within a fine-grained sandstone (Fig. 5C), ident-
ical to the style of preservation of T. ( Trimerus ) harrisoni at
PL 1820, West Brunswick (Fig. 5B) where most specimens
(58%) are complete exoskeletons. The relative abundance of W.
lilydalensis at PL 1804 is very low (2%), exceptionally under-
represented in an assemblage of relatively high diversity
(8 species). By contrast, all other specimens of the species

including isolated tergites and partly disarticulated exo-
skeletons occur in thick-bedded siltstones at various localities
in the Lilydale area. The relative abundance of the species in
the siltstones ranges between 6% and 100%, with assemblages
comprising one to six species in which W. lilydalensis is
moderately under-represented or over-represented (Fig. 4). In
the siltstones of the Eden Park Formation in the Eden Park area
T. (R.) otisi occurs in monospecific assemblages or dominates a
low diversity assemblage also containing rare Odontochile
formosa. In these beds T. (R.) otisi is preserved predominantly
as isolated sclerites or partly articulated exoskeletons, many of
which can be recognised as moult assemblages. The holotype is
a complete exoskeletion with the cephalon displaced and lying
underneath the thoracopygon. The ratio of articulated speci-
mens is 25%, 5% being typical phacopid moult assemblages
and less than 1% being fully articulated individuals. T. (R.) otisi
also occurs in the overlying Clonbinane Sandstone Member, in
medium grained sandstone and coquinal bioclastic lags. At
PL300, Clonbinane it is under-represented (relative abundance
17%) in a higher diversity assemblage also containing
Echidnops hollowayi, O. formosa, Dicranurus sp. and an

10

Andrew C. Sandford

Figure 5 A, D. Moult assemblages of Trimerus ( Edgillia ) kinglakensis in the upper siltstones at PL252, Middendorps Quarry, Kinglake West,
Humevale Siltstone. A, upper right, displaced and inverted cephalon lying underneath thoracopygon (only anterior margin visible); left, thora-
copygon with displaced and rotated cephalon. D, thoracopygon with displaced and rotated cephalon. B-C. Complete dorsal exoskeletons in sand-
stone bioclastic coquinas. B, Trimerus ( Trimerus ) harrisoni from PL 1820, Brunswick, Melbourne Formation. C, Wenndorfia lilydalensis from
PL 1805, Coldstream. Humevale Siltstone.

odontopleurid. More than one third of all trilobites in these beds
are complete, fully articulated exoskeletons. As in the bedded silt-
stones and coquinal lags at Middendorps Quarry, the assemblage
at PL300 is associated with a rich echinoderm fauna.

The taphonomy of the trilobite exoskeleton is an important
palaeoenvironmental indicator. The multitude of sclerites of
which the exoskeleton was composed responded in a complex
way to the depositional environment in which they were
ultimately preserved. Detailing the proportions of fragmented
tergites, convex-up tergites, articulated tergites, enrolled
individuals and moult assemblages in trilobite populations
from the Middle Devonian Hamilton Group, New York, Speyer
and Brett (1986) defined a sequence of trilobite taphofacies
(taphofacies 1A-B, 2A-B, 3A-B and 4A-C) interpreted to
reflect depth and rates of sedimentation. Sandford (2002)

described a similar depth-related sequence of trilobite taphofa-
cies for the phacopid-dominated assemblages (TpI-TpIV) and
the homalonotid-dominated assemblages (ThI-ThIV) of the
Late Silurian-Early Devonian of south-eastern Australia.
Whilst there is some credit in distinguishing between
taphonomies for thick-shelled forms and thin-shelled forms in
shallower facies, these forms occur in both phacopids and
homalonotids. The separate Tp-Th classification of tapho-
nomies is not justified, and abandoned here in place of a
broader TI-IV classification, which can be more widely applied
to trilobite taphofacies. Although this study is based almost
entirely on museum specimens and the proportion of convex-up
specimens cannot be accurately determined, Speyer and Brett’s
taphofacies can be recognised for the homalonotid faunas of
south-eastern Australia. Assemblages preserved in fine-grained

Homalonotid trilobites from the Silurian and Lower Devonian

11

articulated dement*
in well wrtcd and
bedded sjndilonrl

in poorly sorted b*ocla*tic
siltstone bt S
coquina*

(moult assemblage*] in
siltstone; few complete
cuoiketiorij

Wenndorfia lityddensh
Trimerus (EdgiHio)jelli

Trimerus (Btgillfa) klngfakensis
Trimenis ( Ramiotis ) otisi

Homalonotus talenti
Homalonotus willion

Dipleura garratti

Trimerus (Trimenis) horrisonl

Trimerus (Trimerus) vomer

Trimenis (Ramioiis) tomczykowae; Trimerus spp.

Trimenis (Ramiotis) rlckardsl

Trimerus (Ramiotis) iani

Figure 6. Facies and environmental distribution of Australian homalonotids.

lithologies with a high relative abundance of moult assem-
blages (or partly disarticulated exoskeletons), a low abundance
or absence of complete, fully articulated exoskeletons, a low
degree of isolated sclerites and low or negligible breakage can
be assigned to Sandford’s taphofacies TIV (-Speyer and Brett’s
taphofacies 4A). The preservation of moult assemblages
indicates deposition at depths below maximum storm wave
base, where current activity was minimal and reworking of
exoskeletal elements was negligible. Assemblages preserved in
poorly sorted bioclastic coquinal lags with a high relative
abundance of complete, outstretched exoskeletons, an absence
of moult assemblages and a moderate degree of breakage can
be assigned to Sandford’s taphofacies Till. This taphofacies is
interpreted to reflect depths around storm wave base and is
analogous to Speyer and Brett’s taphofacies 3A, although dif-
fering from it in the lower representation of moult assemblages
and enrolled specimens relative to outstretched specimens. The
basal lags represent proximal tempestites generated from the
peak of storm activity, during which highest energy currents
rapidly concentrated and buried large bioclasts (both living and
dead), with complete exoskeletons representing smothered
individuals.

Taphofacies associations for Wenndorfia lilydalensis,
Trimerus ( Edgillia ) kinglakensis and Tn'merus ( Ramiotis ) otisi
populations demonstrate that the low diversity, homalonotid-
dominated assemblages inhabited deeper bathymetries than the
higher diversity assemblages in which homalonotids are under-
represented. A similar relationship can be demonstrated for
populations of Digonus wenndorfi from the Heathcote
sequence, but in a shallower water context. At several localities
including the type locality PL2204, Heathcote, D. wenndorfi
occurs in abundance in monospecific or very low diversity
assemblages. The taphonomy is characterised by a high relative
abundance of isolated sclerites (80-95%), minimal breakage
and a high concentration of elements, with the articulated spec-
imens mostly represented by cephala. Thick-bedded, medium
to coarse-grained, well-sorted sandstone lithologies are associ-
ated with this taphofacies. Sandford (2002) designated this
preservation taphofacies Til, equivalent to Speyer and Brett’s
(1986) taphofacies IB, and it is interpreted to reflect deposition
at depths around normal wave base, where moderate energy
current action gently winnowed finer sediments, and disartic-
ulated and concentrated skeletal elements in coarser lithologies.
At PL2327, Heathcote D. wenndorfi occurs in a high diversity

12

Andrew C. Sandford

fauna of ten species as a proportionally represented species
(relative abundance 11%). The assemblage is dominated by
Echidnops hollowayi and Odontochile formosa. In contrast to
the preservation of the D. wenndorfi- dominated assemblages,
that at PL2327 is characterised by a high proportion of iso-
lated and broken sclerites (broken specimens 20%, isolated
sclerites 98%). This preservation is generally associated with
coarser-grained lithologies, typically thick, coquinal sand-
stone with poorly sorted, randomly oriented bioclasts and can
be assigned to Sandford’s taphofacies TI, equivalent to
Speyer and Brett’s taphofacies 1A. A high proportion of iso-
lated and broken sclerites suggests an environment of deposi-
tion in very shallow environments (<20 m) above normal
wave base, with medium to high energy oscillatory wave-
generated currents reworking, fragmenting and winnowing
skeletal elements.

The paired assemblages occur variously in very shallow,
moderate or deep water facies that reflect specific environ-
mental tolerances and preclude the definition of discrete
assemblage-facies associations. The facies distribution of
south-eastern Australian homalonotids is shown in Fig. 6.

The relationship between homalonotid-dominated low
diversity assemblages in deeper water facies and high diversity
assemblages in which homalonotids are minor faunal elements
in shallower-water facies are not generally consistent with
Mikulic’s (1999) and Thomas’ (1979) observations that homa-
lonotid species dominating shallow- water assemblages occur
as rare elements of assemblages in deeper facies. For Digonus
wenndorfi, Trimerus ( Edgillia ) kinglakensis and Trimerus
( Ramiotis ) otisi the opposite is true, being under-represented or
rare in shallower environments and dominant in deeper
environments. Rather than declining in abundance in even
deeper environments, species are replaced by a different
species. T. (E.) kinglakensis inhabits the deeper environments
of the Lochkovian, whereas T (E.) jelli and D. wenndorfi
inhabit the contemporary shallow and very shallow environ-
ments. Similarly, T. ( R .) otisi inhabits the deeper environments
of the late Ludlow, whereas T (R.) thomasi inhabits the con-
temporary shallow environments. An exception is the distribu-
tion of W. lilydalensis, which is consistent with both the pattern
described above and with the observations of Mikulic and
Thomas. As noted above, W. wenndorfi is rare in the shallower
coquinal sandstones at PL 1804 and dominates many of the
trilobite faunas in the deeper siltstones of the upper Humevale
Siltstone at Lilydale. In the siltstones, the association of
Acastella frontosa and W. lilydalensis alternates with another
association of calymenids and/or phacopids, variously com-
prising Sthenarocalymene angustior (Chapman, 1915),
Nephranomma debrae, N. lynnae and Lochkovella longisulcata
(Shergold, 1968). The latter association is dominant in the
deepest water facies, with taphonomies including enrolled indi-
viduals and often occurring with Harpidella sp. in abundance.
At the few localities where the association of A. frontosa and
W. lilydalensis occurs in these deepest water facies it is only in
low abundance with the calymenid-phacopid associations
dominant. These mixed faunas resemble the deeper water
equivalents of Thomas’ Acaste-Trimerus association, where
Calymene becomes common.

Systematic palaeontology

The description of the homalonotid trilobites from central Victoria is
based on collections in Museum Victoria (NMV), registered with pre-
fix P. This collection includes specimens previously held by the
Geological Survey of Victoria (previously registered with prefix GSV)
and the University of Melbourne, Geology Department. Other speci-
mens cited include those at the Geological Survey of New Zealand
(NZGS) (registered with prefix AR) and at the Canterbury Museum,
Christchurch, New Zealand (registered with prefix ZFc). Trilobite
specimens are preserved in mudstones as internal and external moulds.
Internal moulds were coated with colloidial graphite, latex peels have
been made from external moulds, and all have been whitened with
a mm onium chloride for photography. Trilobite localities are registered
with prefix PL in Museum Victoria. These include previously pub-
lished fossil localites of Jutson (1908: pi. 3), Thomas (1940a, 1940b,
1941, 1956, 1960), Gill and Banks (1950), Gill (1940: fig.l; 1945: fig.
2), Talent (1964: fig. 1), Williams (1964: fig. 2), Moore (1965: fig.l),
VandenBerg (1970), Garratt (1972, 1977), Jell and Holloway (1983:
fig. 1), Holloway and Sandford (1993: fig. 1), Wall et al. (1995: fig. 1)
Rickards and Sandford (1998: fig. 6) and Sandford (2000: fig. 7; 2002:
fig. 1; 2003: text-fig. 1; 2004: fig. 1; 2005: figs 2-4). Trilobite local-
ities in the Heathcote, Kilmore-Kinglake West, Springfield and
Lilydale areas are shown in Figs 8, 11 and 23.

Terminology used in this study for the description of the trilobite
exoskeleton (Fig. 7) generally follows current standard nomenclature
reviewed by Whittington (1997) and Whittington and Kelly (1997).
Terminology specific to the description of homalonotid trilobites has
been introduced by Tomczykowa (1975), Wenndorf (1990) and
Whittington (1993). Wenndorf established several new terms including
‘AuBendom’, referred to as the posterolateral pleural spine in this
work, and the ‘Gelenkleiste’ in reference to ridges that overhang and
partly enclose the trench-like furrow traversing each thoracic segment.
Wenndorf also established a set of measurements and derived ratios
specifically for the description of homalonotids. In accord with
Wenndorf, the glabellar width is measured across LI -LI rather than the
across occipital ring (where the axial furrows are very poorly defined)
and the pygidial axial width is measured across the second axial ring
rather than the first ring, for the same reason. To avoid ambiguity this
width is referred to as the preoccipital glabellar width. However in this
work, following the description of other trilobites, the glabellar length
includes the length of the occipital ring and the pygidial axial length
includes the length of the terminal axial piece. Whittington (1993)
introduced the term ‘articulating and pleural furrow’ to describe the
furrow traversing thoracic segments, considered to be homologous to
the independent pleural and articulating furrows of other trilobites.
‘Rib-ring offset’ is a term introduced in this work to describe differ-
ences in segmentation of the pygidial axis and pleural lobe in homa-
lonotids. Rib-ring offset is a modification of R-P ratios often described
for encrinurids, but impractical in describing homalonotid pygidia
where segmentation is often poorly defined or effaced posteriorly. It is
expressed by the n-th pleural rib when the transverse midline of that rib
intersects with the axial furrow opposite a pygidial ring furrow.

Order PHACOPID A Salter, 1864

Suborder CALYMENINA Swinnerton, 1915

Superfamily CALYMENOIDEA Burmeister, 1843

Family Homalonotidae Chapman, 1890

Remarks. Organisation of the Homalonotidae here follows
Thomas (1977) who discussed previous divisions of the family.

Subfamily Homalonotinae Chapman, 1890

Homalonotid trilobites from the Silurian and Lower Devonian

13

CEPHALON (DORSAL VIEW)

connective suture (dorsal section)
rostral suture
preglabellar field
preglabellar furrow
axial furrow

r

iK

median indentation
frontal lobe
glabellar lobes (L1-L3)
lateral glabellar furrows (SI -S3)
apodemal pit
muscle scar

CEPHALON (VENTRAL VIEW)

rostral plate (ventral section)
librigenal doublure

posterior branch of facial suture
(ventral section)

THORACIC SEGMENT (OF 13)

PYGIDIUM (DORSAL VIEW)

articulating half ring
articulating furrow
articulating facet

inter-ring furrow
axial ring

axial furrow

rostral plate (dorsal section)
anterior branch of facial suture
preocular fixigenal field
. eye ridge

lateral border furrow
palprebral area
palpebral lobe
visual surface

subocular groove
librigenal field
sutural furrow

posterior branch of facial suture
(dorsal section)

postocular fixigenal area
paraglabellararea (ala)
posterior border furrow
posterior border

anterior wing

anterior lobe of middle body

lateral border furrow

macula

middle furrow

posterior lobe of middle body
posterior border furrow
median notch
posterior border lobe

articulating half ring

articulating and pleural furrow

anterior band of pleura
articulating facet
posterior band of pleura
axial furrow

axial articulating process
axial ring

pleural furrow
pleural rib
lateral border
lateral border furrow

V hypostome

pleural

lobe

posterior axial swelling
terminal axial piece
postaxial ridge/ field

terminal pygidial spine

Figure 7. Morphological terms for the homalonotid exo skeleton.

14

Andrew C. Sandford

Genera and subgenera included. Homalonotus Konig, 1825, Trimerus
( Trimerus ) Green, 1832, Trimerus ( Ramiotis ) subgen. nov., Trimerus
( Edgillia ) subgen. nov., Digonus Gtirich, 1909, Dipleura Green, 1832,
Brongniartella Reed, 1918, Burmeisteria Salter, 1865, Burmeisterella
Reed, 1918, Scabrella Wenndorf, 1990, Arduenella Wenndorf, 1990,
Parahomalonotus Reed, 1918, Platycoryphe Foerste, 1919,
Wenndorfia gen. nov.

Discussion. Classifications of the Homalonotinae by Reed
(1918), Sdzuy (1959), Tomczykowa (1975), Thomas (1977)
and Wenndorf (1990) have variously emphasised particular
features of the exoskeleton including glabellar lobation, glabel-
lar outline, the course of the cephalic suture, the length of the
preglabellar field, the morphology of the anterior cephalic mar-
gin, the shape of the rostral plate, the expression of a rostral
process, eye position, pygidial outline, the outline of the
pygidial axis, and the expression and degree of pygidial seg-
mentation as characters of generic significance. Differences
between these classifications reflect different emphases on
diagnostic characters. The diversity of morphologies expressed
within genera is greatly enhanced by the Australian fauna and
necessitates a review of current generic concepts. A new genus
Wenndorfia and two new subgenera Trimerus {Ramiotis) and
T. ( Edgillia ) are described, and revised diagnoses are given for
Trimerus, Homalonotus, Dipleura, Digonus and
Parahomalonotus.

Homalonotus Konig, 1825

Homalonotus Konig, 1825:104.

Koenigia Salter, 1865: 119.

Type species. Homalonotus knightii Konig, 1825 from the Ludlow of
England, by monotypy. The type species has been recorded from
Britain, Germany, Poland and Canada, although its the relationship to
the Canadian H. dawsoni is not clearly established. Hall (1860)
described dawsoni solely from pygidia, and his diagnosis clearly allies
the species with knightii and the Swedish H. rhinotropis. McLeam
(1924) suggested that differences in pygidial morphology easily dis-
tinguish dawsoni from knightii, citing the posterior projection of the
pygidial axis, narrower proportions and less convex profile of the lat-
eral margin as distinguishing the type species. On these criteria
McLeam identified specimens from the McAdam and Moydart
Formations at Arasaig, Nova Scotia as knightii, and those from the
slightly younger Stonehouse Formation in the same area as dawsoni.
The cephalic morphology of dawsoni was described by Dawson (1868,
1877) and McLeam. McLearn noted that the two cephala known from
the McAdam and Moydart Formations were very similar to those of
dawsoni from the Stonehouse Formation. Indeed, a relatively unde-
formed cephalon from the Moydart Formation examined by the author
is clearly attributable to dawsoni rather than knightii. The specimen is
comparable to the Stonehouse Formation cephala in the anterior place-
ment of the eyes and more elongate and more-weakly tapering glabel-
lar shape, distinguishing the Canadian species from the type species.
The specimen also shows the acutely pointed lateral cusps of the ante-
rior margin, not previously documented. Whether the differences in
pygidial morphology between the McAdam and Moydart Formation
populations are significant is a question that cannot be resolved with-
out detailed re-examination of the faunas.

Other species included. Homalonotus dawsoni Hall, 1860, H.
rhinotropis Angelin, 1852, H. williamsi sp. nov., H. talenti sp. nov.

Range. Ludlow, possibly early Pndoli . England, Germany, Poland,
Sweden, eastern North America and south-eastern Australia.

Revised diagnosis. Cephalon much wider than long. Glabella
long (length 1.1- 1.3 times width), tapering forward weakly to
moderately (15-30°), sides straight, lobation weak to indistinct.
Paraglabellar area distinct. Preglabellar furrow present, of vari-
able depth (shallow to very deeply impressed). Preglabellar
field very short (<0.08 times cranidial length). Anterior margin
of cephalon tricuspid with a strongly folded (M- shaped) profile
in dorsal view. Central cusp triangular, and strongly convex
downwards in anterior view. Facial suture and rostral suture
meeting at invagination of anterior margin such that connective
suture is absent dorsally. Eyes forwardly placed, opposite
0.55-0.7 glabellar length. Pygidial lateral border furrow
distinct, anteriorly lateral border swollen, lip-like, fused ven-
trally with rolled doublure and continuous with long (exsag.)
articulating facet.

Discussion. Sdzuy’s (1959) diagnosis of Homalonotus reiter-
ates the characters listed by Reed (1918), omitting only the
‘angular course of the anterior branch of the facial suture’.
Additional characters listed by Sdzuy include features of the
glabella (indistinct lobation, trapezoidal shape), the rostral plate
(lacking a process), the folding of the anterior margin, and the
presence of a cephalic border (i.e. that defined by the preg-
labellar furrow). The preglabellar furrow is variable in depth,
being very deeply impressed in H. williamsi and H. talenti,
moderately impressed in H. dawsoni (see McLearn, 1924: pi.
27, fig. 14) and H. rhinotropis (see Angelin, 1878: pi. 20, fig.
1). In the type species, the depth of the preglabellar furrow
varies from shallow (e.g. Tomczykowa, 1975: pi. 1, figs 1, 3) to
moderately impressed (e.g. Salter, 1865: pi. 12, fig. 2) and sug-
gests the presence/absence rather than the depth of the furrow
is of significance.

The assignment of two new Australian species to the genus
indicates a somewhat broader range of morphologies for the
genus than represented by the northern hemisphere species,
particularly in features of the pygidium. Homalonotus knightii,
H. rhinotropis and H. dawsoni share a distinct pygidial mor-
phology characterised by raised, long pleural ribs that are con-
tinuous with the axial rings (separated by a deep, continuous,
pleural and ring furrows), effaced axial furrows, by a fused
postaxial ridge and posterior area of pleural field, and by a
strongly acuminate tip. In contrast, the pygidial axial furrows of
H. williamsi and H. talenti are only moderately impressed (Figs
10.3-10.11). In williamsi the axis is raised, defining distinct
pygidial trilobation, the postaxial ridge is not fused with the
posterior area of the pleural field, whilst in talenti the pleural
and ring furrows are shallow and the posterior tip is rounded.
The revised diagnosis given above accommodates these mor-
phologies by excluding all pygidial characters listed in Sdzuy’s
(1959) and Tomczykowa’s (1975) diagnoses, including the
‘acuminate triangular and acutely tipped pygidial outline’, the
‘weakly defined trilobation’, the ‘posterior fusion of axis and
pleural field’ and the ‘distinct segmentation’. Nevertheless, the
pygidial morphology characterising the contemporary northern-
hemisphere species defines a species group distinct from the
Australian taxa and reflects a degree of provincialism not
otherwise seen in homalonotid distribution.

The distinctive morphology of the pygidial lateral border is

Homalonotid trilobites from the Silurian and Lower Devonian

listed as an additional diagnostic character. The complex anter-
ior cephalic margin of Homalonotus corresponds to a complex
coaptive morphology. Laterally, the swollen, lip-like section of
the pygidial border-doublure defines the overlap of the libri-
gena, the pygidial border-doublure fitting against the cephalic
doublure. The pygidial doublure is narrow posterior to the lip-
like section, and at this point the doublure of the enrolled
pygidium emerged from underneath the anterior cephalic
border at the invagination of the anterior margin. The anterior
margin of the rostral process fitted against the posterior margin
of the pygidial doublure, as indicated by the matching convex-
ity of these structures (in anterior/posterior view) in H. talenti
(Figs 9.5b, 10.7c).

Several of the cephalic features listed as generic characters
by Sdzuy (1959) are excluded from the revised diagnosis,
including the ‘indistinct glabellar lobation’ and the ‘median
point on the rostral suture’. These characters are excluded to
accommodate the Australian species, that lack a median point
on the rostral suture, whilst Homalonotus williamsi exhibits
weak glabellar lobation. Sdzuy noted the difficulty in interpret-
ing the anterior border of Homalonotus. However, the junction
of the facial suture and rostral suture at the invagination of the
anterior margin (and the absence of the connective suture
dorsally) is clearly evident on williamsi, and is comparable to
the morphology of the anterior margin of H. rhinotropis
described by Moberg and Gronwall (1909).

Sdzuy (1957), Tomczykowa (1975) and Thomas (1977)
considered Homalonotus to have been derived from Trimerus
and interpreted H. ( T .) johannis Salter, 1865 as transitional
between the genera. Wenndorf (1990) expressed uncertainty on
this derivation of Homalonotus. Reed (1918) tentatively placed
johannis in Homalonotus, primarily on account of its tricuspid,
folded anterior margin and supposed pygidial similarities, but
noted that long preglabellar field of johannis differed markedly
from that of H. knightii. Although Prantl and Pribyl (1948)
suggested a new genus or subgenus be erected for johannis,
Sdzuy (1957) retained the species in Homalonotus. The length
of the preglabellar field is only one of many differences
between knightii and johannis indicating that these species are
not related. Whilst johannis shares with the northern hemi-
sphere species of Homalonotus ( knightii , H. dawsoni and
H. rhinotropis ) deeply impressed pygidial pleural and ring fur-
rows and an elongate, acutely tipped triangular outline, it lacks
the effaced trilobation and fused postaxial area characterising
those species. More importantly, johannis lacks the swollen
lip-like pygidial border shared also by the Australian species
and considered diagnostic of the genus. The species also differs
markedly from Homalonotus in having a highly derived
cranidial morphology. The raised glabella which is markedly
expanded across LI -LI (tr.) and has deep SI apodemes and a
distinct sagittal ridge, the strong expression of the medial
indentation of the anterior glabellar margin and paraglabellar
areas, and the long and weakly convex (tr.) preglabellar field
indicates assignment of Salter’s species to Trimerus (Trimerus),
in agreement with Tomczykowa’s (1975) and Morris’ (1988)
assignment.

Of the species assigned in this work to Homalonotus,
H. williamsi appears to be the least derived. H. williamsi retains

15

Figure 8. Geological sketch map of the Heathcote area showing
Wenlock-Lochkovian fossil localities yielding homalonotids. For other
fossil localities see also Thomas (1940a, 1940b, 1941, 1956), Talent
(1964, fig. 1), Sandford (2002, fig. 1A; 2005, fig. 4).

16

Andrew C. Sandford

distinct glabellar lobation, the axial furrows are moderately
impressed, the pygidial axis is raised posteriorly and the
postaxial area is not fused with the pleural field. In these
respects williamsi shares features of Trimerus possibly reflect-
ing the relationship suggested by Sdzuy, Tomczykowa and
Thomas. The interpretation of williamsi as morphologically
primitive supports the derivation of Homalonotus from
T. ( Ramiotis ) rather than from the more derived T. (Trimerus).
Of species assigned to T. (Ramiotis), williamsi bears closest
resemblance to T. (R.) otisi (Fig. 20), which bears a well-devel-
oped tricuspid cephalic margin comparable to that of T. (T.)
johannis, though more weakly folded. As with several other
Upper Silurian species of T. (Ramiotis), otisi also a exhibits a
well defined pygidial border furrow and swollen lip-like border
comparable to that of Homalonotus, a morphology otherwise
only poorly developed or absent in other groups including
T. (Trimerus) and T. (Edgillia). T. (R.) otisi lacks the strongly
derived glabellar features of johannis, sharing with Homa-
lonotus the elongated, weakly tapering glabella with weak
lobation. In these respects otisi is a more likely candidate than
johannis in representing an intermediate morphology between
Trimerus and Homalonotus, although its interpretation as an
ancestral species is not in accord with its stratigraphic position,
otisi appearing in strata immediately overlying those yielding
williamsi.

Homalonotus talenti sp. nov.

Figures 9, 10.5-10.11

Homalonotinae gen. et sp. indet. 2. — Holloway and Neil, 1982: 146,
fig. 4I-L. — Morzadec, 1986: 186.

Type material. Holotype NMY P304936 (cephalon) from PL6650,
Heathcote, Victoria (Fig. 9.1). Paratypes NMV P304927, NMV
P304937-P304939 (cephala), NMV P304923-P304925, NMV
P304928, P304929 (cranidia), NMV P304941, NMV P304943 (libri-
gena), NMV P304946-P304948 (hypostomes), NMV P304945, NMV
P304949 (thoracic segments), NMV P304917, P304918, NMV
P304920-P304922 (pygidia) from PL6650. Paratypes NMV P304952,
P304953 (pygidia) from PL6651, Heathcote. For localities see Fig. 8.
Previously figured material. NMV P78296 (ex GSV35724, cephalon,
figured Holloway and Neil, 1982: figs 41, 4J), NMV P78297 (ex
GSV35725, pygidium, figured Holloway and Neil, 1982: figs 4K, 4L)
from PL2239, Thomas locality F25, Parish of Heathcote, Heathcote.
For locality see Fig. 8.

Registered material. 127 specimens: 10 cephala, 41 cranidia, 9 librige-
nae, 3 hypostomes, 8 thoracic segments, 56 pygidia. NMV

P3049 1 7-P30495 1 , NMV P304959-305026 from PL6650. NMV
P304952-P304957, NMV P305027-P305029 from PL6651. NMV
P304958, NMV P305041 from PL2265, Thomas locality F46, Parish
of Heathcote, Heathcote. NMV P78296, P78297 from PL2239. NMV
P305030-P305040 from PL2207, Thomas locality F7, Parish of
Dargile, Heathcote. For localities see Fig. 8.

Stratigraphic distribution. Upper beds of the Mclvor Sandstone and
lowermost beds of the Cornelia Member of the Mt Ida Formation,
Notoparmella plentiensis Assemblage Zone, late Ludlow. The age of
the Mclvor Sandstone is constrained by early Ludlow (upper nilssoni
Biozone) graptolite assemblages from the underlying Melbourne
Formation (Rickards and Sandford, 1998). In Europe, Homalonotus
occurs in abundance in strata of Ludfordian age, occurring rarely in the
Gorstian (Thomas et al., 1989) and possibly ranging into the Pr idoli.
The first appearance of H. talenti about 380 m above the base of the
Mclvor Sandstone (at PL2265) is considered here to approximate the
Gorstian-Ludfordian boundary. The Ludlow-Pridoli boundary can be
placed within the interval between the last appearance of talenti (at
PL2239) and the first appearance of the post-Ludlow brachiopod
Cyrtina at a slightly higher horizon, 50-100 m above the base of
Cornelia Member.

Derivation of name. For John A. Talent (Macquarie
University), for his contribution to Victorian palaeontology.

Diagnosis. Glabella trapezoid, sides straight and converging at
20°, anterior margin broadly rounded. Glabellar length about
1.1 times preoccipital glabellar width and 0.94 times cranidial
length. Preglabellar furrow very deeply impressed. Eye placed
with midline of palpebral lobe opposite 0.56 glabellar
length/0.52 cranidial length. Dorsal surface of rostral plate 0.14
times cephalic length. Hypostome with length 0.85 width, lobes
on the posterior border with length 0.17 times hypostomal
length. Pygidium with length about 0.9 times width, postaxial
ridge projecting posteriorly, tip rounded. Pygidial axis with
width 0.5 times pygidial width, 11 axial rings. Axial furrows
straight and tapering at about 30°. 7 pleural ribs, rib-ring
medially offset at fourth rib. Ring, pleural and axial furrows
shallow to moderately impressed.

Description. Exoskeleton of moderate size, maximum length estimat-
ed 12 cm (from NMV P305923), occipital convexity (tr.) moderate,
pygidial convexity (tr.) strong.

Cephalon wide, length 0.6 times width, with trapezoid outline, sides
moderately convex and converging forwards at about 75°, anterior
margin tricuspate, median cusp triangular in outline with rounded tip,
length about 0.6 times width, lateral cusps with obtusely angled tips
reaching forward to midlength of median cusp. Cranidial width 1.9

Figure 9. Homalonotus talenti sp. nov. la, holotype NMV P304936, cephalon, dorsal view X 3.0 (latex cast) from PL6650. lb, same, x 2.6 (inter-
nal mould), lc, same, lateral view x 3.0 (latex cast). 2, paratype NMV P304938, cephalon, dorsal view x 2.6 (latex cast) from PL6650. 3, paratype
NMV P304929, cranidium, dorsal view x 2.1 (internal mould) from PL6650. 4, paratype NMV P304923, cranidium, dorsal view x 1.65 (internal
mould) from PL6650. 5a, paratype NMV P304927, cephalon, dorsal view x 5.5 (internal mould) from PL6650. 5b, same, anterior view x 5.0.
6, paratype NMV P304937, cephalon, dorsal view x 1 .9 (latex cast) from PL6650. 7, paratype NMV P304924, cranidium, dorsal view x 3.6 (inter-
nal mould) from PL6650. 8a, paratype NMV P304939, cephalon, dorsal view x 2.0 (internal mould) from PL6650. 8b, same, x 2.1 (latex cast).
9, paratype NMV P304943, librigena, dorsolateral view x 1.22 (latex cast) from PL6650. 10, paratype NMV P304925, cranidium, dorsal view
x 1.75 (internal mould) lfom PL6650. 11, paratype NMV P304928, cranidium, dorsal view x 1.6 (internal mould) from PL6650. 12, paratype
NMV P304949, thoracic segment, lateral view x 1.75 (internal mould) from PL6650. 13, paratype NMV P304945, thoracic segment, dorsal view
x 1.4 (internal mould) from PL6650. 14, paratype NMV P304941, librigenal doublure, ventral view x 2.4 (latex cast) from PL6650. 15, paratype
NMV P304947, hypostome, ventral view x 2.2 (internal mould) from PL6650. 16a, paratype NMV P304946, hypostome, ventral view x 3.4 (latex
cast) from PL6650. 16b, same (internal mould). 17a, paratype NMV P304948, hypostome, ventral view x 3.5 (internal mould) from PL6650. 17b,
same (latex cast).

Homalonotid trilobites from the Silurian and Lower Devonian

17

mm

18

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

19

times length. Glabella with anterior margin strongly defined, arc of
curvature centred at about glabellar midlength. Occipital ring about 0.1
times cranidial length, slightly wider medially. Occipital furrow mod-
erately impressed to shallow, with weak forward flexure medially.
Glabellar lobation extremely weak (best seen on NMV P304928) to
indistinct. LI 0.32 times glabellar length, L2 0.12 times glabellar
length, L3 0.10 times glabellar length and frontal lobe 0.20 times
glabellar length. SI weakly convex, directed diagonally abaxially. S2
and S3 transverse. Axial furrows shallow to moderately impressed.
Paraglabellar area very weakly defined. Length (sag.) of preglabellar
furrow and ridge-like preglabellar field 0.03 times cranidial length.
Length (exsag.) of posterior border equal to occipital length adaxially,
lengthening slightly abaxially. Posterior border furrow transverse, very
wide and shallow, meeting lateral border furrow distally. Postocular
fixigenal area long, length (exsag.) 0.25 times cranidial length.
Palpebral lobes placed anteriorly and remotely (6-6 1.5 times preoc-
cipital glabellar width). Palpebral lobe length (exsag.) 0.15 times
cranidial length, palpebral furrow indistinct. Preocular fixigenal area
of moderate width, width 0.17 5-6 adjacent to palpebral area, eye
ridges not distinct, narrowing markedly anteriorly. Anterior branches
of facial suture converging at about 80°, curving inwards opposite the
antero-lateral corner of the glabella and converging at about 140°
anteriorly. Librigena with wide, moderately impressed border furrow,
not continuing forward of antero-lateral comer of glabella, librigenal
field weakly convex, steeply inclined, lateral border wide, convex. Anter-
ior margin of librigena projecting far forwards from juncture of rostral,
connective and facial sutures at cephalic margin as triangular cusp.

Course of rostral suture broadly rounded, concentric to anterior
margin of glabella. Dorsal surface of rostral plate rounded triangular,
length (sag.) 0.4 times width, strongly concave (tr. sect.). On cephalic
doublure connective sutures straight and weakly converging posterior-
ly. Librigenal doublure without distinct vincular furrow, strongly con-
vex (exsag. sect.) adjacent to connective suture (i.e. accommodating
preglabellar furrow). Hypostomal suture very broadly rounded.

Hypostome with middle furrow shallow to moderately impressed,
anterior wing process small (width 0. 1 times hypostomal width), lobes
on posterior border parabolic in outline, deep medial notch with sides
converging at about 75°.

Thorax with axial furrows poorly defined. Pleural furrows narrow
(exsag.) and deep, pleural tips rounded.

Pygidium with triangular outline, sides weakly convex and con-
verging at about 80°. In lateral view pygidium high, height equal to
length. Pygidial axis reaching to about 0.8 times pygidial length, con-
tinuous posteriorly with wide postaxial ridge. Postaxial ridge raised,
parallel-sided, wide, width (tr.) 0.45 times axial width, posterior mar-
gin with parabolic outline. Axial furrows tapering, curving to the
exsagittal posteriorly, shallow anteriorly, moderately impressed poster-
iorly. Pleural furrows shallowing markedly adjacent to border furrow.
Border furrow moderately impressed opposite pleural field, shallow
opposite postaxial ridge. In dorsal view border narrow (tr.) but pro-

tuberant from margin of pleural field. In lateral view border very wide
anteriorly, merging with wide articulating facet, narrowing markedly
posteriorly. Lateral border continuous with narrow pygidial doublure.
In posterior view anterior margin of pygidium strongly convex, poster-
ior margin with distinct medial and lateral arches. In ventral view,
inner margin of doublure parabolic in outline with deep medial inden-
tation.

Dorsal exoskeleton finely granulose. Pygidial border with fine ridging.
Discussion. Holloway and Neil (1982) suggested the affinities of an
incomplete cephalon examined by them were with Homalonotus. Their
suggestion is confirmed with the additional specimens listed. They
noted similarities between the associated pygidium and that of the
South American Lower Devonian species H. clarkei, but these similar-
ities are superficial. Following Cooper (1982), and as discussed below,
clarkei is assigned to Burmeisteria.

Hypostomes are also known for Homalonotus knightii and H.
rhinotropis (Salter, 1865: pi. 12 fig. 10; Angelin, 1878: pi. 20 fig. lc).
The hypostome of H. talenti most closely resembles that of the type
species. The hypostome of rhinotropis is relatively elongate (length
times 1.1 width) compared to that of knightii (length 0.81 times width)
and talenti (length 0.85 times width). The projections of the posterior
margin are broadly based and long in talenti and knightii, but short in
rhinotropis.

Although the ventral surface of the rostral plate of Homalonotus tal-
enti is not known, the course of the connective sutures (indicated by
the shape of the librigenae) is more or less straight and slightly con-
vergent posteriorly, indicating the rostral plate to be approximately
pentagonal, with subequal sides. Apparent curvature of the connective
sutures on Fig. 9.14 is due to the oblique orientation of the specimen.

The broad, rounded medial indentation of the inner margin of the
pygidial doublure of Homalonotus talenti (Fig. 10.7e) differs from that
of H. knightii, in which the margin is more or less straight laterally, and
defines an acute angle medially (see Salter, 1865: pi. 12 fig. 9a,
Tomczykowa, 1975: pi. 1 fig. 5c).

Environmental notes. Throughout its range Homalonotus talenti occurs
in thick-bedded fine- to medium-grained sandstones, in low diversity
or monospecific assemblages. At the type locality where the species
occurs in greatest abundance the proportion of articulated specimens is
low (6%) and the proportion of broken specimens low (3%).The fauna
can be assigned to taphofacies Til and indicates shallow environments
around normal wave base.

Homalonotus williamsi sp. nov.

Figures 10.1-10.4

Type material. Holotype NMV P308674 (cephalon) from PL6615,
Jutson locality VII, Eden Park, Victoria (Fig. 10.1). Paratypes NMV
P308675 (pygidium), NMV P308676 (cephalon) from PL6615.
Paratype NMV P304511 (pygidium) from PL6614, Jutson locality VI,
Eden Park. For localities see Fig. 1 1 .

Figure 10.1-10.4 Homalonotus williamsi sp. nov. la, holotype NMV P308674, cephalon, dorsal view x 2.1 (internal mould) from PL6615. lb,
same, anterior view, lc, same, oblique view x 2.3 (latex cast). Id, same, dorsal view. 2a, paratype NMV P308676, cranidium, dorsal view x 1.3
(internal mould) from PL6615. 2b, same, lateral view x 1.2. 2c, same, anterior view x 1.3. 3, paratype NMV P308675, pygidium, oblique view
x 3.0 (latex cast) from PL6615. 4a, paratype NMV P304511, pygidium, oblique view x 1.35 (internal mould) from PL6614. 4b, same, dorsal view
x 1.45.

Figure 10.5-10.11, Homalonotus talenti sp. nov. 5a, paratype NMV P304952, pygidium, dorsal view x 1.1 (latex cast) from PL6651. 5b, same,
posterodorsal view. 6, paratype NMV P304953, pygidium, oblique view x 1.2 (latex cast) from PL6651. 7a, paratype NMV P304921, pygidium,
lateral view X 1.6 (internal mould) from PL6650. 7b, same, dorsal view. 7c, same, posteroventral view. 7d, same, posterior view. 7e, same,
ventral view (doublure). 8a, paratype NMV P304917, pygidium, posteroventral view x 1.2 (internal mould) from PL6650. 8b, same, dorsal view
x 1.6. 8c, same, lateral view x 1.4. 9, paratype NMV P304918, pygidium, dorsal view x 2.6 (latex cast) from PL6650. 10, paratype NMV P304920,
pygidium, lateral view x 2.7 (internal mould) from PL6650. 11, paratype P304922, pygidium, dorsal view x 1.5 (internal mould) from PL6650.

20

Andrew C. Sandford

Figure 11. Geological sketch map of the Springfield- Kinglake West area showing Llandovery -Lochkovian fossil localities yielding homalonotids.
For other fossil localities see also Jutson (1908, pi. 3), Thomas (1960), Talent (1964, fig. 1), Williams (1964, fig. 2), Garratt (1972, 1977), Rickards
and Sandford (1998, fig. 6), Sandford (2002, fig. 1C; 2005, figs 2-3).

Other material. NMV P304512 from PL6614.

Stratigraphic distribution. Macropleura band, Eden Park Formation
(130-140 metres above base of unit), lowermost Notoparmella
plentiensis Assemblage Zone, early-mid Ludlow.

Derivation of name. For George E. Williams, for his contri-
bution to Victorian stratigraphy.

Diagnosis. Cephalon wide, length 0.6 times width. Glabella
long, length 1.15 times width, sides more or less straight, taper-

ing at about 15°, anterior margin broadly rounded, arc centred
at 0.55 glabellar length. Glabellar length 0.92 times cranidial
length. Glabellar lobation distinct, SI and S2 expressed as deep
notches adjacent to the axial furrows but very shallow abax-
ially, placed opposite 0.43 and 0.63 glabellar length respec-
tively. Axial furrows moderately impressed on internal moulds
(shallow on external moulds), preglabellar furrow very deeply
impressed. Rostral plate with length of dorsal surface 0.11
times cephalic length, width (across rostral suture) 1.9 times

Homalonotid trilobites from the Silurian and Lower Devonian

length, triangular. Genae moderately swollen, lateral border
furrow moderately impressed. Eye placed with midline of
palpebral lobe opposite 0.67 glabellar length. Anterior branch
of facial suture with posterior section straight and strongly con-
vergent (at about 90°), anterior section evenly curving to the
transverse. Rostral suture weakly convex. Pygidium triangular
in outline, sides straight, converging posteriorly at about 100°.
Axial furrows moderately impressed. Pygidial axis strongly
convex, raised, sides converging at about 25°, continuous pos-
teriorly with wide postaxial ridge. Pleural field with 7 ribs.
Pleural and ring furrows moderately impressed, of subequal
depth.

Discussion. Homalonotus williamsi closely resembles
H. talenti from the lower Ludlow-lower Pndolf strata of the
Heathcote area. Differences in cephalic morphology are subtle,
but talenti can be distinguished in that the glabella is less elon-
gate (glabellar length 1.1 times width) SI -S3 are extremely
weakly impressed to indistinct, the axial furrows are much
shallower, the preglabellar furrow and preglabellar field are
notably shorter (exsag. and sag., glabellar length 0.95 times
cranidial length), the eyes are more posteriorly placed (midline
of palpebral lobe opposite 0.55 glabellar length), and the rostral
process is wider posteriorly and only weakly convex down-
wards. The pygidium of williamsi is known only from frag-
ments, but differs from that of talenti in having deeper axial,
ring and pleural furrows.

In addition to the pygidial characters and the very deep,
trench-like preglabellar furrows distinguishing the two
Australian species from the northern-hemisphere species,
Homalonotus talenti and H. williamsi also share straight and
strongly convergent anterior branches of the facial sutures, in
contrast to the convex outwards course of the sutures in
H. knightii, H. dawsoni and H. rhinotropis. The Australian
species and rhinotropis share a rounded anterior glabellar
margin, differing from the transverse margin of knightii and
dawsoni.

Environmental notes. See Dipleura garratti sp. nov.
Brongniartella Reed, 1918

Type species. Homalonotus bisulcatus Salter, 1851 from the Upper
Ordovician of England, by original designation.

Brongniartella sp.

Trimerus sp. — Holloway and Sandford, 1993: 93, fig. 4L, non figs
4C-D, 4F-G, 41- J, 4N-P.

Material. NMV PI 37228 (pygidium, figured Holloway and Sandford,
1993: fig. 4L) from PL359, Tiger Range, northwest of Maydena,
Tasmania. For locality see Holloway and Sandford: fig. 1 .

Stratigraphic distribution. Richea Siltstone, Monograptus
griestoniensis-M. crenulata biozones, upper Llandovery.

Notes. The elongate, rounded parabolic outline of the pygid-
ium, the strongly raised, narrow, convex pygidial axis and the
indication of a distinct border suggest assignment to
Brongniartella. The concave sides of the axis is shared with
other species of Brongniartella. The species is a late appear-
ance for Brongniartella, a predominantly Upper Ordovician

21

genus but known to extend into the Lower Llandovery atavus-
cyphusl biozones in Britain (Temple, 1975) and also recorded
from the Lower Llandovery of Jordan (Wolfart et al., 1968).
The Upper Llandovery Tasmanian record narrows the gap
between Lower Llandovery Brongniartella and the youngest
known species, B. pamiricus (Balashova, 1966) from the
Wenlock of Pamir, central Asia.

Digonus Giirich, 1909

Type species. Homalonotus gigas Roemer, 1843, from the Lower
Devonian (Emsian) Kahleberg Sandstone, Germany, by original
designation.

Other species and subspecies included. Burmeisteria ( Digonus )
antarcticus Saul, 1965, D. armoricanus Pillet, 1961a, D. asturco
Kegel, 1927, Homalonotus crassicauda Sandberger and Sandberger,
1849, D. gigas posterior Wenndorf, 1990, H. goniopygaeus
Woodward, 1882, H. (D.) harpyius Richter and Richter, 1932, H. inter-
medius Vietor, 1919, H. laticaudatus Williams and Breger, 1916,
H. (D.) ornatus disornatus Richter and Richter, 1932, D. ornatus
linguatus Wenndorf, 1990, H. ornatus Koch, 1883a, D. comes
Chlupac, 1981, H. roemeri de Koninck, 1876, D. wenndorfi sp. nov.,
Trimerus zeehanensis Gill, 1949, D. zemmourensis Pillet, 1961b,
Digonus sp. A in Wenndorf (1990).

Other species tentatively included. Digonus collini Renaud, 1942,
Homalonotus derbyi Clarke, 1890.

Range. Lochkovian-Emsian.

Diagnosis. Cranidium trapezoidal in outline, anterior margin
with median cusp. Dorsal section of connective sutures very
short. Glabella trapezoidal in outline, sides straight or very
weakly concave. Glabellar lobation very weak or absent.
Paraglabellar area distinct. Anterior outline of cranidium
quadrate, anterior branches of facial suture more or less straight
between palpebral lobe and midlength of preglabellar field and
converging at an acute angle (20-60°), curving abruptly to the
transverse anteriorly. Rostral suture transverse to weakly con-
cave. Ventral surface of rostral plate with thorn, spine or keel.
Pygidium triangular to elongate triangular, with wide axis
(0.5-0.7 times pygidial width). Axis with weak independent
convexity (tr. sect.), postaxial ridge not raised. Pleural and ring
furrows deep to very deep, more or less equal in depth. Axial
furrow shallow or moderately impressed posteriorly, very shal-
low or effaced anteriorly, anteriormost ribs and rings fused,
with corresponding section of axial furrow effaced or reduced
to shallow invagination in posterior margin of segment. Pleural
furrows maintaining uniform depth to a point close to border.
Border furrow and border poorly defined. Rib-ring offset high
(fifth-seventh rib).

Discussion. Previous diagnoses for Digonus are brief. Giirich
(1909) listed the truncate and indented outline of the cephalic
anterior margin, the angular margin of the antero-lateral corners
of the cranidium, the pointed pygidial tip and the weakly
tapered, trapezoid glabellar outline. Reed (1918) emphasised
the strong expression of the pygidial segmentation as a further
diagnostic character. Sdzuy (1959) included the absence of
glabellar lobation and angular pleural tips as diagnostic charac-
ters although, as he regarded Digonus as a subgenus of
Burmeisteria, other characters were incorporated into the

22

Andrew C. Sandford

generic concept. These included the distinct paraglabellar area,
the presence of a ventral process on the rostral plate, a triangu-
lar pygidial outline, distinct pygidial trilobation, and a poorly
expressed postaxial ridge. Tomczykowa (1975) omitted many
of Sdzuy’s characters from her revised diagnosis, closely fol-
lowing Reed. In emending Tomczykowa’s diagnosis, Wenndorf
(1990) noted the presence of weak glabellar lobation in some
species, and that early representatives of the genus have less
elongate pygidial outlines.

The revised diagnosis given here adds substantially to the
list of diagnostic characters and qualifies other characters pre-
viously used. A substantially restricted concept of the genus is
proposed by placing new emphasis on pygidial characters
including the relative depth of pygidial ring and pleural
furrows, the expression of the axial furrows, the expression of
the postaxial ridge and the width and convexity of the pygidial
axis. The revised diagnosis emphasises differences between
Digonus, Trimerus and Burmeisteria, and results in sub-
stantially different assignments of the species listed by
Tomczykowa (1975) and Wenndorf (1990).

Tomczykowa (1975) and Wenndorf (1990) considered
Digonus to have been derived from Trimerus. The genera are
certainly close, many of the characters listed in the diagnosis of
Digonus occurring variously in species of Trimerus. Although
the presence of a rostral keel or process is considered of pri-
mary importance in differentiating the genus from Trimerus, it
is the combination of characters that defines Digonus. Other
cephalic characters, particularly the degree of glabellar loba-
tion, the quadrate course of the facial and rostral sutures, and
the trapezoid glabellar outline, distinguish Digonus from most
species of Trimerus. Pygidia of Digonus can generally be dis-
tinguished from those of Trimerus by the deeper pleural and
ring furrows that are more or less equal in depth, by the
shallower axial furrows, and by the less convex axis and
postaxial ridge. For the morphologically convergent species, it
is the continuity of the axial furrow anteriorly in Trimerus (and
the fusion of the anteriormost axial ring and pleural rib in
Digonus) that distinguishes the genera. Hence, Homalonotus
crassicauda from the Emsian of Germany, known only from
pygidia and previously interpreted as a temporally disjunct
representative of Trimerus (Wenndorf, 1990, Schraut, 2000)
clearly belongs in Digonus. The Lochkovian North American
H. major Whitfield, 1881 is best assigned to Trimerus rather
than to Digonus, because the pygidial axial furrow is deep and
distinct anteriorly.

Digonus wenndorfi and D. zeehanensis from the lower
Lochkovian of south-eastern Australia are the best known of
the early representatives of Digonus and support the derivation
of this genus from Trimerus. D. wenndorfi and the French
D. roemeri are the earliest Digonus, occurring immediately
above the Silurian-Devonian boundary and suggesting a latest
Silurian origin for the genus. In cranidial features, wenndorfi
and zeehanensis show close affinities to the D. omatus group
from the middle Pragian-Emsian of Europe rather than to the
D. gigas group (see Wenndorf, 1990) whose members share
longer preglabellar fields. Weak glabellar lobation and short
pygidia with markedly obtuse (120-130°) angular tips set
wenndorfi and zeehanensis apart from later members of the

genus, with the exception of several species (D. antarcticus and
D. omatus disornatus ) that retain weak lobation, and several
others that have similarly short pygidia (e.g. D. armoricanus
and D. crassicauda ). In addition to weak glabellar lobation and
short pygidial proportions, wenndorfi also exhibits a moder-
ately raised pygidial postaxial ridge (Figs 12.6, 12.12-12.18).
In these features wenndorfi can be considered a ‘primitive’
Digonus, with relict features of Trimerus retained. D. zeehan-
ensis bears a short (sag.) but wide (tr.) median cephalic cusp
(Fig. 13.1) intermediate in morphology between the large semi-
circular cusps of Trimerus on species such as T. ( Ramiotis ) otisi
and T. ( Trimerus ) johannis, and the small, acute cusps of
Emsian Digonus. The anteriorly distinct pygidial axial furrows
of roemeri (see Morzadec, 1986: pi. 32 figs 1, 4, 6-7) and (to a
lesser extent) wenndorfi, can also be interpreted as a Trimerus-
like feature, although the wide pygidial axis and equally deep
pleural and ring furrows indicates their affinities with other
Digonus.

Emphasising the significance of the transverse anterior
margin of the cranidium and the depth of the pygidial pleural
and ring furrows, Tomczykowa (1975) derived Digonus from
Trimerus, suggesting T. ( Trimerus ) johannis as a transitional
morphology between the genera. Thomas (1977) doubted this
suggestion, emphasising the difference in age between T. (T.)
johannis (late Wenlock) and the first appearance of Digonus
(earliest Lochkovian). Wenndorf (1990) interpreted European
Lochkovian species such as Homalonotus vialai Gosselet in
Gosselet et al., 1912 and H. roemeri as representing early
Digonus morphologies, noting similarities to the Polish Ludlow
T. permutus Tomczykowa, 1978 (=T. lobatus Tomcykowa,
1975 non Prouty, 1923 in Swartz and Prouty). A more plausible
transitional morphology is represented by the upper Ludlow
T. ( Ramiotis ) otisi. The similarities of this species to contem-
porary Homalonotus have been discussed above, but its
similarities to species of Digonus are more marked. In addition
to having a tricuspid cephalic margin, otisi exhibits a sub-
quadrate course of the facial and rostral sutures, weak glabellar
lobation, straight- sided glabellar outline, deep pleural and
equally deep ring furrows, and a pygidial axial furrow that is
indistinct anteriorly (Fig. 20). In the latter feature, otisi is an
exception amongst congeners. However, the flat rostral plate,
the long glabellar proportions, the narrow proportions of the
pygidial axis and the raised postaxial ridge demonstrate its
close affinities to Trimerus.

Digonus wenndorfi and D. zeehanensis demonstrate the con-
servative Digonus cephalic morphology to have been already
established in the earliest Lochkovian. European species con-
sidered by Tomcykowa (1975) as representing early Digonus
morphologies, including Homalonotus vialai, D. bostoviensis
and D. elegans, are variably assigned below to Paraho-
malonotus and Wenndorfia, and exhibit few of the diagnostic
cephalic or pygidial features of Digonus. In particular, the
anterior branches of the facial sutures of these species are
broadly curved and converge at a strongly obtuse angle
opposite the preglabellar field, giving the anterior margin of
the cranidium a more rounded/parabolic outline. Burmeisteria
( Digonusl ) delattrei Pillet and Waterlot, 1982 from the Emsian
of France exhibits few features typical of Digonus. It has a

Homalonotid trilobites from the Silurian and Lower Devonian

23

raised pygidial axis, a raised postaxial ridge with a posteriorly
projecting spine, anteriorly distinct axial furrows and a
moderately convex (tr.), elongate glabella. The pygidial
morphology, including the posteriorly projecting axis, indicates
assignment to Burmeisterella. Wenndorf (1990) questionably
assigned the Brazilian Homalonotus oiara Hartt and Rathbun,
1875 to Digonus, but their emphasis on the concavity of
the sides of the glabella is not compatible with the quadrate
glabellar outline considered here as diagnostic of Digonus.
The forward eye position exhibited by the single cranidium
known suggests affinities with Burmeisteria rather than
with Dipleura.

Relationships between Digonus and Burmeisteria have been
variously interpreted. Sdzuy (1959) considered Digonus to
be a subgenus of Burmeisteria. Tomczykowa (1975) listed
several differences between the taxa, emphasising the
absence of spines and glabellar lobation in Digonus to support
its independent status. Cooper (1982) argued that the range of
variation in the course of the rostral suture, the degree
of glabellar lobation and the glabellar outline in the highly
polymorphic type species B. herschelii (Murchison, 1839)
overlapped with morphologies typical of Digonus. Following
the emphasis placed by Sdzuy on these characters, Cooper
regarded Digonus as junior synonym of Burmeisteria.
Wenndorf (1990) questioned many of the differences listed
by Tomczykowa, noting a convergence in morphologies
between Burmeisteria and Digonus, but nevertheless main-
taining their independent status. Kennedy (1994) noted that
the pygidial doublure of Digonus, unlike that of Burmeis-
teria, is often narrower and bears a narrow groove in the
margin of the pygidial doublure. This distinction between the
genera also applies to Burmeisterella, which Kennedy consid-
ered as a junior synomym of Burmeisteria. The independent
status of Burmeisterella is supported here, with high
generic significance accorded to the very short (sag.) pre-
glabellar field and the morphology of the pygidial axis,
which is raised high rather than fused with the pleural field
posteriorly, and extends posteriorly over the margin as a
narrow-based to spinose tip. In addition, the pygidium of
Burmeisterella has a more convex lateral margin, and
always bears a pair of prominent, large nodes or spines on the
anteriormost pleural rib. The independent status of Bur-
meisteria and Digonus is supported in this work. The taxa can
be readily distinguished morphologically, despite the extreme
polymorphism exhibited by herschelii. In Burmeisteria, the
pygidial axial furrow is impressed anteriorly, and the
pygidial pleural and ring furrows are typically shallower than
those of Digonus and shallow posteriorly. Burmeisteria is
further characterised by a high number of pygidial segments
(>13 axial rings). Cranidia of Burmeisteria and Digonus may
exhibit morphological convergence, but a glabellar outline
markedly expanded across LI -LI (tr.) or with concave sides,
and well defined lateral glabellar furrows immediately
distinguish Burmeisteria when present.

Following Hennig (1965), Wenndorf suggested that the
mutually exclusive palaeogeographic ranges of Burmeisteria
and Digonus represented a significant taxonomic feature
supporting their independent status. Digonus wenndorfi.

D. zeehanensis and D. antarctica extend the range of the genus
into temperate palaeolatitudes of north-eastern Gondwana.
However, the palaeogeographic ranges of the genera remain
mutually exclusive. B. herschelii is restricted to lower palaeo-
latitudes of southern Gondwana, occurring in southern Africa,
the Falkland Islands and South America. The reassignment of
several South American taxa to Burmeisteria emphasises the
provincialism of the genus (see Table 1), perhaps as early as the
Late Silurian. Homalonotus linares Salter, 1861, assigned
below to Burmeisteria (see Trimerus) occurs in the Late
Silurian of Bolivia and Uruguay.

Affinities of the Lochkovian Homalonotus noticus Clarke,
1913 (?= H. caorsi Mendez-Alzola, 1938) from South America
and possibly South Africa (see Cooper, 1982) are with
Burmeisteria. Reed (1918) initially assigned the species to
Burmeisteria but later reassigned it to Digonus (Reed, 1925).
Sdzuy (1957) suggested that the species represents a transi-
tional form between Burmeisteria and Digonus. The distinct
S1-S3, the narrow pygidial axis and the anteriorly continuous
pygidial axial furrow are incompatible with assignment to
Digonus. Tomczykowa (1975) and Wenndorf (1990) assigned
H. noticus to Trimerus, but the presence of a rostral projection,
a sinusoidal rostral suture and high pygidial segmentation (up
to 13 axial rings) excludes the species from the genus as
defined here.

Homalonotus clarkei from the Lower Devonian South
America (?= H. buqueti Mendez-Alzola, 1938, ?= H. spat-
ulirostris Mendez-Alzola, 1938), has been variably assigned to
Digonus (Wolfart, 1968), to Trimerus (with question,
Tomczykowa, 1975), to Burmeisteria (Cooper, 1982) and to
Dipleura (Wenndorf, 1990). The strongly folded anterior
cephalic margin excludes assignment to Trimerus, as this taxon
is characterised in this work by having a flat rostral plate. The
very shallow pygidial pleural furrows and somewhat deeper
ring furrows of clarkei are typical of Dipleura, but the tricuspid
anterior cephalic margin, the quadrate and medially concave
anterior cranidial margin, and the strong forward tapering of the
glabella do not conform to this assignment. The weakly
expressed pygidial segmentation excludes the species from
Digonus as defined here. The generic affinities of the species
are uncertain.

Burmeisteria ( Digonus ) accraensis from the Devonian of
Ghana exhibits weak pygidial furrows, excluding the species
from Digonus as defined in this work. The taxon has been vari-
ably assigned to Trimerus (Tomczykowa, 1975) and to Dipleura
(with question, Wenndorf, 1990), but the presence of a rostral
process (see Saul, 1967: pi. 143 fig. 6) excludes the species from
these genera.. The species is assigned here to Burmeisteria.

Digonus wenndorfi sp. nov.

Figs 3, 12, 22.1-22.6

Trimerus ( Dipleural ) sp. — Talent, 1964: 49 (pars), pi. 26 figs 1, 2
non text-fig. 6.

Homalonotidae gen. et sp. indet. 1. — Holloway and Neil, 1982: 145,
figs 4A-H.

Type material. Holotype NMV P304717 (pygidium) from PL2203,
Thomas locality F3, Parish of Dargile, Heathcote, Victoria (Fig.

24

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

25

12.17). Paratypes NMV P304709-P304716 (cranidia), NMV P304874
(librigena), NMV P304872, P304872 (thoracic segments), NMV
P304717, NMV P304860-P304866, NMV P304868 (pygidia) from
PL2203. Paratype NMV P304913 (librigena) from PL2327, Heathcote.
For localities see Fig. 8.

Previously figured material. NMV P78295 (ex GSV 39474, pygidium,
figured Holloway and Neil, 1982: figs 4E, 4H), NMV P59656 (ex GSV
39200 pygidium, figured Talent, 1964: pi. 26 fig. 2, Holloway and
Neil, 1982: figs 4F, 4G), NMV P59655 (ex GSV 39476, pygidium, fig-
ured Talent, 1964: pi. 26 fig. 1) from PL2203. NMV P78293 (thoracic
segment, figured Holloway and Neil, 1982: fig. 4C), NMV P78294
(thoracic segment, figured Holloway and Neil, 1982: fig. 4D) from
PL2202, Thomas locality F2, Parish of Dargile, Heathcote. NMV
P78292 (cephalon, figured Holloway and Neil, 1982: figs 4A, 4B)
from PL2204, Thomas locality F4, Parish of Dargile, Heathcote. For
localities see Fig. 8.

Registered material. 88 specimens: 2 cephala, 12 cranidia, 4 librigenae,
17 thoracic segments, 53 pygidia. NMV P59655, P59656, NMV
P78295, NMV P82882, NMV P82886, NMV P304709-P304717,
NMV P304859-P304903 from PL2203. NMV P78293, P78294, NMV
P82880, NMV P82883-P82885, NMV P304904 from PL2202. NMV
P82941, NMV P304905-P3049 14 from PL2327. NMV P78292 from
PL2204.

Stratigraphic distribution. Mt Ida Formation, from about 400 m above
the base of the Dealba Member up to about the 100 m above the base
of the Stoddart Member, Boucotia janae Assemblage Zone, early
Lochkovian. The first appearance of Digonus wenndorfi at PL2204 is
close stratigraphically to the first appearance of Boucotia (see Garratt,
1983: fig. 7) and together support a basal Lochkovian age for these
horizons.

Derivation of name. For Dr Klaus-Werner Wenndorf
(Germany), for his contribution to the study of homalonotids.

Diagnosis. Glabella trapezoid, length 1.0- 1.2 times width, sides
straight and converging at about 20° opposite genae, anterior
margin of glabella well defined with medial indentation
moderately impressed to indistinct. Glabellar lobation weak to
indistinct. Axial furrows moderately impressed opposite genae.
Palpebral lobe short, 0.1 times cranidial length, placed with
midline opposite 0.5 glabellar length/0.39 cranidial length.
Preglabellar field long, length (sag.) 0.22 times cranidial
length. Rostral suture transverse. Pygidium triangular, sides
moderately convex and converging posteriorly at 85-100°, tip
angular. Pygidial axis with width 0.5-0.6 times pygidial width,
11-12 axial rings, ring furrows deep, continuous with raised

postaxial ridge. Axial furrows poorly defined opposite
first-second axial rings, moderately impressed posteriorly,
straight and tapering at 30-40°. Pleural furrows deep. 8-9
pleural ribs, rib-ring medially offset at fifth rib.

Description. Exoskeleton large (maximum length estimated 25 cm
from NMV P304860), occipital convexity (tr.) moderate, pygidial
convexity (tr.) strong. Dorsal exoskeleton finely granulose.

Cranidia with elongate and short forms. Elongate form with
cranidial width about 1.6 times length, short form with cranidial
width about 1.9 times length. Glabella with length 0.78 times cran-
idial length, anterior margin very broadly rounded to transverse.
Elongate form with glabellar length 1.2 times width, short form with
glabellar length equal to width. Occipital ring with length 0.1 times
glabellar length. Occipital furrow deeply impressed, with weak for-
ward flexure medially. Glabellar lobation (best seen on NMV P304715
and NMV P304710) with LI 0.28 and L2 0.15 times glabellar length
respectively. SI straight and directed posteromedially at about 17°
from the transverse, S2 weakly convex forwards and transverse, S3
indistinct. In some specimens (e.g. NMV P304710, P304711) SI mod-
erately impressed for short distance adjacent to axial furrow. Axial
furrows very shallow and directed diagonally opposite occipital ring.
Paraglabellar area weakly defined (best seen on NMV P304711).
Length (exsag.) of posterior border equal to occipital length adaxially,
lengthening slightly abax-ially. Posterior border furrow transverse,
very wide, moderately impressed, terminating distally. Postocular fix-
igenal area very short, length (exsag.) 0.16 times cranidial length.
Palpebral lobes placed remotely (5-6 1.67 times preoccipital glabellar
width/0.7 times cranidial width). Palpebral furrow weak to moderately
impressed. Preocular fixigenal area of moderate width, 0.17 times 5-6
narrowing slightly anteriorly. Preglabellar field weakly concave (tr.
sect.). Anterior branches of facial suture angular, directed exsagittaly
for a short distance adjacent to the eye (to a point opposite 0.7 glabel-
lar length), anteriorly converging at about 40° in elongate forms
and 60° in short forms. Librigena without distinct border furrow or
lateral border. In anterior view anterior margin of librigenae
moderately convex.

Thorax with axial furrows indistinct. Pleural furrows wide and
deep.

Pygidia with long form and narrow form, sides converging poster-
iorly at about 85° in narrow form and 100° in wide form. Pygidial axis
with width about 0.5 times pygidial width in wide form, 0.6 in narrow
form. Pygidial axis reaching to about 0.85 times pygidial length,
raised, continuous posteriorly with postaxial ridge. Postaxial ridge
wide, width 0.3 times axial width. Axial furrows straight and tapering
at about 33° in narrow form, 38° in wide form, curving to the exsagit-
tal posteriorly. Pleural furrows not reaching margin. Border furrow and
border not defined. In posterior view posterior margin of pygidium

Figure 12. Digonus wenndorfi sp. nov. 1, paratype NMV P304715, cranidium, dorsal view x 1.25 (internal mould) from PL2203. 2a, paratype
NMV P304714, cranidium, dorsal view x 1.6 (internal mould) from PL2203. 2b, same (latex cast). 3a, paratype NMV P304709, cranidium,
dorsal view x 0.75 (internal mould) from PL2203. 3b, same, lateral view. 3c, same, dorsal view (latex cast). 4, paratype NMV P304716, cran-
idium, dorsal view x 1.2 (internal mould) from PL2203. 5a, paratype NMV P30471 1, cranidium, dorsal view x 1.75 (internal mould) from PL2203.
5b, same (latex cast). 5c, same, oblique view (internal mould). 6, paratype NMV P304868, pygidium, dorsal view x 1.0 (internal mould) from
PL2203. 7a, paratype NMV P304872, thoracic segment, lateral view x 2.3 (internal mould) from PL2203. 7b, same, dorsal view. 8, paratype NMV
P304874, librigena, ventral view (doublure) x 1.75 (latex cast) from PL2203. 9, paratype NMV P304913, librigena, lateral view x 1.7 (internal
mould) from PL2327. 10, paratype NMV P304873, thoracic segment, dorsal view x 2.0 (internal mould) from PL2203. 11, paratype NMV
P3047 12, cranidium, dorsal view x 1 .25 (latex cast) from PL2203. 12, paratype NMV P304864, pygidium, dorsal view x 1 .4 (internal mould) from
PL2203. 13, paratype NMV P304861, pygidium, dorsal view x 1.8 (latex cast) from PL2203. 14, paratype NMV P304860, pygidium,
ventral view (doublure) x 1.25 (internal mould) from PL2203. 15, paratype NMV P304863, pygidium, dorsal view x 1.5 (internal mould)
from PL2203. 16, paratype NMV P304865, pygidium, dorsal view x 1.7 (latex cast) from PL2203. 17a, holotype NMV P304717, pygidium,
lateral view x 1.1 (internal mould) from PL2203. 17b, same, dorsal view x 1.3. 17c, same, x 1.1 (latex cast). 18, paratype NMV P304862,
pygidium, lateral view x 1.5 (internal mould) from PL2203.

26

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

horizontal. In lateral view dorsal profile of axis inclined at about 30° to
the horizontal, postaxial ridge very steeply inclined.

Discussion. Digonus wenndorfi is abundant and dominates the
trilobite fauna at several localities. Except for a cephalon
(Holloway and Neil, 1982: figs 4A, 4B) the species is known
only from isolated tergites. Relative proportions of many
features (eg. glabellar and pygidial length/width ratios) are dif-
ficult to ascertain due to deformation. Nevertheless, two
distinct forms of wenndorfi can be recognised, elongate and
short morphs differing in the relative proportions of the
cephalon, glabella and pygidium. These morphs are not related
to size, nor are they products of deformation as their ranges in
size overlap, and they occur together on the same bedding plane
(Fig. 3). The differing morphological proportions within the
population are strongly bimodal rather than continuous.
Pygidial length-width ratios range between 0.76-0.93 (average
0.86) in the short morphs, in the long morphs between
1.11-1.12. Similarly, glabellar length-width ratios range
between 0.96-1.00 (average 0.99) in the short morphs, in the
long morphs between 1.15-1.23 (average 1.19). Similar
observations have been made for populations of D. gigas and
attributed to sexual dimorphism (Dahmer, 1914), although
Wenndorf (1990: table 31) demonstrated, with a much larger
sample size of 67 pygidia, that the variation in gigas is con-
tinuous rather than bimodal, with intermediate forms being the
most numerous, and so not reflecting sexual dimorphism.
Although the sample size for wenndorfi is much smaller (11
measurable specimens) the complete absence of intermediate
forms (e.g. pygidia with length-width ratios range between
0.93-1.1) is statistically significant. Whether the bimodality
reflects sexual dimorphism is uncertain, although the narrower
morphs strongly outnumber the wider morphs and so suggest
that it does not.

The subquadrate outline of the anterior part of the
cranidium, the weakly tapered trapezoid glabellar outline,
the wide pygidial axis, and the depth of the pygidial ring and
pleural furrows clearly indicate assignment to Digonus.
D. wenndorfi differs markedly from the D. gigas group and
more closely resembles the D. ornatus group in having a
relatively longer preglabellar field, wide fixigenae anteriorly,
and a transverse rather than weakly concave anterior cranidial
margin.

Digonus wenndorfi differs from most Pragian-Emsian
species of Digonus in lacking the elongate, straight-sided tri-

27

angular outline and a long produced tip characteristic of the
type and other taxa such as D. ornatus and D. intermedius. In
having shorter pygidial proportions, wenndorfi more closely
resembles other Lochkovian species, including D. laticaudatus
from North America, D. armoricanus from France, and D. roe-
meri from Europe. Compared to Pragian-Emsian species,
Lochkovian species of Digonus lack some of the features
characterising Digonus. These species can be interpreted as
reflecting ancestral morphologies, as might be expected in the
earliest representatives of a genus. ‘Trimerus- like’ features
including the raised postaxial ridge and weak glabellar lobation
of wenndorfi can be interpreted in this context.

Of Lochkovian species of Digonus, only D. zeehanensis
from Tasmania (redescribed below) is known sufficiently for
detailed comparison with D. wenndorfi. These taxa are very
close, but the latter differs in having slightly concave glabellar
sides, a longer glabella, more distinctly expressed glabellar
lobation, a shorter preglabellar field, a much shorter pygidium
with a relatively narrower pygidial axis, a more obtusely-
angled pygidial tip, and a lower postaxial ridge (Fig. 13).
With the exception of the latter, these features suggest that
zeehanensis represents a less derived morphology.

Digonus roemeri is a near-contemporary of D. wenndorfi,
recorded from the base of the Lochkovian ( [hesperius zone) in
Europe (Chlupac et al., 2000). The species is poorly docu-
mented and, as noted by Tomczykowa (1975), a number of taxa
have been assigned to it. Topotypes of D. roemeri (Morzadec,
1986: pi. 32 figs 1, 4, 6-10) share with wenndorfi short
pygidial proportions and the equally deep pygidial pleural and
ring furrows typical of Digonus. D. roemeri differs from
wenndorfi in that the pygidial axis is wider and the postaxial
ridge is not raised. In contrast to other species assigned to the
genus, pygidia of roemeri and the comparable D. laticaudatus
exhibit anteriorly continuous pygidial axial furrows,
interpreted here to reflect the ancestral morphology.

Many species assigned to Digonus are poorly documented
and comparison with D. wenndorfi is difficult. From Europe,
D. harpyius is known only from a rostral plate. The Emsian
D. goniopygaeus from England and D. crassicauda from
Germany are kn own only from pygidia. Despite the compar-
able short proportions, the pygidium of crassicauda differs
from that of wenndorfi in having a weakly defined postaxial
ridge and a narrow, recurved flange defining the pygidial tip
(Wenndorf, 1990: pi. 9 figs 1-3), as in other Emsian Digonus.
The Antarctic D. antarcticus differs markedly from wenndorfi

Figure 13. Digonus zeehanensis (Gill, 1949). la, NMV P304656, cephalon, dorsal view x 1.2 (internal mould) from PL1726. lb, same, enlarge-
ment of anterior margin x 2.5. 1c, same, lateral view of cephalon x 1.0. Id, same, dorsal view x 1.25 (latex cast). 2a, NMV P304657, cephalon,
dorsal view x 2.6 (internal mould) from “Little Henty River”. 2b, same, lateral view x 2.25. 3, NMV P304650, hypostome, ventral view x 2.2
(internal mould) from PL1726. 4a, NMV P304653, librigena, dorsolateral view x 1.3 (latex cast) from PL1726. 4b, same, lateral view. 5, NMV
P304652, thoracic segment, lateral view x 3.0 (latex cast) from PL1726. 6, NMV P14789, cranidium, dorsal view x 0.9 (latex cast) from PL1726.
7a, holotype NMV P14590, cranidium, dorsal view x 1.3 (latex cast) from PL1726. 7b, same, internal mould x 1.1. 8, NMV P304683, hypostome,
ventral view x 2.1 (latex cast) from PL1726. 9, NMV P304658, cranidium, dorsal view x 1.6 (latex cast) from PL6653. 10, NMV P304649,
pygidium, dorsal view x 1.1 (internal mould) from PL1726. 11, NMV P304655, cranidium, dorsal view x 1.0 (latex cast) from PL1726. 12, NMV
P7651, pygidium, dorsal view x 1.65 (internal mould) from “MtZeehan”. 13a, NMV P304648, pygidium, lateral view x 1.1 (internal mould) from
PL1726. 13b, same, dorsal view. 14, NMV P14787, pygidium, dorsal view x 0.75 (latex cast) from PL1726. 15a, paratype NMV P14592,
pygidium, lateral view x 1.0 (internal mould) from PL1726. 15b, same, dorsal view (latex cast). 15c, same, dorsoposterior view (internal mould).
15d, same, dorsal view. 16, NMV P304659, pygidium, dorsal view x 1.0 (latex cast) from “Mt Zeehan”.

28

Andrew C. Sandford

in having weakly expressed pygidial axial furrows, exception-
ally deep pleural furrows and a poorly expressed postaxial
ridge (Saul, 1965: pi. 17 figs 1-11).

Holloway and Neil (1982) considered specimens of Digonus
wenndorfi to be close to Trimerus lilydalensis Gill, 1949, also
from the Lochkovian of central Victoria. The availability of
many new specimens of wenndorfi and a revision of Gill’s
species does not support this comparison, with the latter
assigned to the new genus Wenndorfia.

Digonus zeehanensis (Gill, 1949)

Figure 13

Trimerus zeehanensis Gill, 1949: 70, pi. 9 figs 1, 2, 4, text-fig.
ID. — Tomczykowa, 1975: 11. — Wenndorf, 1990: 16. — Holloway and
Sandford, 1993: 93. — Schraut, 2000: 382.

Type material. Holotype NMV PI 4590 (cranidium, counterpart pre-
viously registered NMV P14591, Fig. 13.7) and paratype NMV
P14592 (pygidium, counterpart previously registered NMV P 1459 13)
from PL1726, Gill and Banks locality 16, Zeehan, Tasmania.

Registered material. 67 specimens: 2 cephala, 13 cranidia, 12 libri-
genae, 2 hypostomes, 11 thoracic segments, 27 pygidia. NMV P14787,
P14788 (counterparts), NMV P14789, NMV P14791, NMV
P304648-P304656, NMV P304662, NMV P304664-P304708 from
PL1726. NMV P304657 from “Little Henty River”, Zeehan. NMV
P304661 from “near Little Henty River”, Zeehan. NMV P304663 from
PL1725, Gill and Banks’ locality 15, Zeehan. NMV P304660, NMV
P304658 from PL6653, Zeehan. NMV P7561, NMV P304659 from
“Mt Zeehan”, Zeehan.

Stratigraphic distribution. Bell Shale, Boucotia australis
Assemblage Zone, mid-late Lochkovian.

Diagnosis. Cephalon trapezoid, sides straight, anterior margin
tricuspate, with short (0.05 times cephalic length) but wide
(length 0.25 times width) median cusp, lateral cusps about half?
the length of the median cusp. Glabella trapezoid, sides
weakly concave and converging at about 20°, length about 1.2
times width, anterior margin well defined, lobation weakly
defined. Axial furrows moderately impressed. Palpebral lobe
placed with midline opposite 0.52 glabellar length/0.42 crani-
dial length. Preglabellar field with length (sag.) 0.17 times
cranidial length. Anterior branches of facial suture straight and
converging at about 50°, curving abruptly to the exsagittal
anteriorly. Rostral suture transverse. Dorsal surface of rostral
plate triangular, short, length 0.15 times width. Hypostome
with middle furrow deep adaxially, shallow abaxially. Posterior
border of hypostome with long lateral lobes of length 0.17
times hypostomal length. Pygidium short, length 0.68 times
width, sides moderately convex and converging posteriorly at
about 110°. Pygidial axis 0.45 times pygidial width, 12 axial
rings, continuous with low postaxial ridge. Axial furrows taper-
ing at about 30°, moderately impressed posteriorly, not contin-
uous anteriorly opposite first ring. Pleural and ring furrows
deep. 8 ribs, rib-ring medially offset at fifth rib. Dorsal
exoskeleton with coarse pitting.

Discussion. The Bell Shale is strongly sheared, resulting in
wide variations in shapes and proportions of specimens.
Because Gill (1949) described the species from a limited

number of specimens, examination of a larger population
reveals a number of inaccuracies in his description. The
concavity of the preglabellar field and the upturning of the
anterior cranidial margin on the holotype (Fig. 13.7), consid-
ered diagnostic of the species by Gill, are features attributable
to tectonic distortion and are absent from other topotype cra-
nidia. Gill recorded lateral glabellar furrows as absent, but they
are weakly defined on most specimens. The pygidial axial fur-
rows are moderately impressed rather than poorly defined.
Despite the abundance of cephalic and pygidial tergites,
thoracic pleurae are unusually rare in the Bell Shale. From the
fragments available, there is no indication of spines on the
thorax as suggested by Gill.

Tomczykowa (1975) and Wenndorf (1990) assigned Gill’s
species to Trimerus, but the quadrate course of the anterior
branches of the facial and rostral sutures, the equally deep
pygidial ring and pleural furrows and the effacement of the
axial furrow anteriorly are more consistent with an assignment
to Digonus. Pygidia have a much wider axis (average width
0.46 pygidial width) than recorded by Gill, who cited the axial
width to be one third the pygidial width. However, as noted
above, the longer glabellar proportions, more distinctly
expressed glabellar lobation, shorter pygidial proportions with
a relatively narrower axis and a more obtusely-angled pygidial
tip suggest that D. zeehanensis represents a less derived
morphology compared to other Digonus. In these features,
zeehanensis is most closely comparable to D. roemeri from the
basal Lochkovian of France.

Environmental notes. Digonus zeehanensis dominates the tr-
ilobite fauna of the Bell Shale. At the best-sampled locality
(PL1726), the relative abundance of D. zeehanensis is >90%.
The fauna is typical of homalonotid-dominated assemblages,
being low diversity and otherwise comprising a proetid, a
cheirurid and a dalmanitid (Gill, 1950). The latter suggests
alignment with the deeper water Trimerus delphinocephalus-
Dalmanites limulurus Community of Mikulic, 1999. The pro-
portion of articulated specimens in populations of zeehanensis
is low. Of the 67 specimens, all are isolated tergites with
the exception of three cephala. Breakage is high in the sampled
populations (Br=27%). Specimens occur on bedding planes
in association with other fossil concentrations or in more
sparsely fossiliferous layers between the lag bands. The taphon-
omy is indicative of taphofacies Till and together with the
lithofacies and biofacies suggests a setting around maximum
storm wave base.

Dipleura Green, 1832

Type species: Dipleura dekayi Green, 1832. From the Middle
Devonian Hamilton Group, New York State, USA, by monotypy.

Other species included. Dipleura boliviensis Wolfart, 1968, D. gar-
ratti sp. nov., D. iberica Wenndorf, 1990, Homalonotus kayseri
Thomas, 1905, H. laevicauda Quenstedt, 1852, = H. simplex Richter
and Richter, 1926, D. lanvoiensis Morzadec, 1969, D. praecox
Tomczykowa, 1975, D. sp. (in Richter and Richter, 1943), D. sp. (in
Morzadec, 1981), D. sp. nov. (in Wenndorf, 1990).

Range. Upper Silurian (mid Ludlow)-Middle Devonian (Givetian).

Homalonotid trilobites from the Silurian and Lower Devonian

29

Revised diagnosis. Cephalon short, length 0.5 to 0.6 times
cephalic width, rounded triangular to semicircular in outline.
Glabella with sides straight or weakly concave, subparallel to
moderately convergent (20°), length 1.1 to 1.25 times width,
without lobation in maturity. Preglabellar field of moderate
length, 0.15-0.18 times cranidial length. Paraglabellar areas
indistinct. Palpebral lobes posteriorly placed, opposite 0.3 to
0.45 cranidial length. Eyes remote, 6-6 generally 1.7-1. 9 times
preoccipital glabellar width. Anterior branches of facial sutures
describing a broad curve and strongly convergent anteriorly,
between 80-100° opposite midlength of preglabellar field.
Rostral suture transverse to moderately convex forwards.
Ventral surface of rostral plate flat, without projection.
Pygidium with weakly defined trilobation, axial furrows very
shallow to effaced. Axis with ring furrows moderately
impressed to effaced, with weak to distinct posterior swelling,
without well defined postaxial ridge. Pleural furrows shallow to
effaced, invariably as shallow or shallower than ring furrows.
Finely papillate ornament.

Discussion. As with Digonus, Parahomalonotus and
Burmeisteria, the type species of Dipleura is one of the
youngest members of the genus and differs significantly from
older forms. General morphological changes in the genus over
time include a trend toward a less tapered glabellar shape with
increasingly concave sides, and a decrease in the definition of
pygidial segmentation and trilobation. In Middle Devonian
species a stronger cephalic convexity is developed, and the
contrast in depth between ring furrows and pleural furrows is
not as marked. The revised diagnosis differs from previous
ones in recognising the limited significance that pygidial out-
line holds as a generic character. In the case of Dipleura , the
oldest (early Ludlow) species, Dipleura garratti from Victoria,
has a long, acuminate triangular-shaped pygidium with an
acutely pointed tip, in contrast to the short parabolic outline and
rounded pygidial tip exhibited by Devonian taxa and consid-
ered characteristic of the genus. The upper Ludlow D. praecox
from Poland has an intermediate morphology, having a short
triangular outline with an angular tip.

Emphasis is placed on several characters listed by
Salter (1865), Reed (1918) and Sdzuy (1959) but omitted
by Tomcykowa (1975) and Wenndorf (1990). These include
the course of the facial and rostral sutures, eye position
and weak expression of paraglabellar areas. Several new diag-
nostic characters are added, including the absence of a
projection or keel on the ventral surface of the rostral plate, the
presence of a weak to distinct posterior swelling of the
pygidial axis and the absence of a well defined postaxial
ridge.

The revised concept of the genus excludes a number of
species that have been previously assigned to Dipleura (see
Wenndorf, 1990: table 1, Tomczykowa, 1975: table 3). These
include Burmeisteria ( Digonus ) accraensis from West Africa,
Homalonotus clarkei from Bolivia, Dipleura salteri Morris,
1988 from England and Trimerus (Dipleura) fornix Haas, 1968
from Turkey. Generic assignment of the two former species is
discussed under Digonus. D. salteri is tentatively assigned to
Trimerus ( Ramiotis ), discussed below. T. (D.) fornix is assigned

below to Wenndorfia, erected for many of the species previous-
ly assigned to Parahomalonotus. Cephalic outline, the stronger
segmentation of the pygidial axis compared to the pleural field,
and the definition of the pygidial axial furrow posteriorly were
considered by Wenndorf (1990) to be important generic char-
acters in distinguishing Dipleura from morphologically con-
vergent species of Parahomalonotus. In restricting
Parahomalonotus to a group close to the type species, the dis-
tinction between the two genera is marked. In particular, the
strong glabellar and pygidial axial convexity, strong glabellar
lobation and strong pygidial segmentation easily separate
members of Parahomalonotus s.s. from those of Dipleura. The
problem of convergence addressed by Wenndorf re-emerges
however, between Dipleura and species assigned below to
Wenndorfia. Dipleura and Wenndorfia share many characters
including a weakly tapering glabellar outline, effaced glabellar
lobation, a posterior eye position, a preglabellar field of mod-
erate length, an effaced pygidial postaxial ridge and pygidial
outlines that are for the most part rounded parabolic. For the
latter character triangular outlines are exceptional, expressed in
early representatives of each genus such as D. garratti and W.
lilydalensis (Gill, 1949). Many species assigned to Wenndorfia
can be immediately distinguished from Dipleura in having dis-
tinct pygidial segmentation, with pleural furrows being moder-
ately to deeply impressed. Such species include W. multicosta-
tus (Koch, 1883a), W. miloni (Renaud, 1942), W. elegans
(Tomcykowa, 1975), W. bostoviensis (Tomczykowa, 1975), W.
plana junior (Wenndorf, 1990) and W. sp. (=Digonus vialai in
Tomczykowa, 1975). However, in a number of taxa the pygidi-
al axial and pleural furrows are weakly impressed to indistinct,
including W. plana plana (Koch, 1883a), W. forbesi (Rouault,
1855) and W. fornix. Assignment of these convergent species to
Wenndorfia is indicated by consistent differences in the course
of the facial sutures between Dipleura and Wenndorfia. In
Dipleura , the facial sutures tend to be more strongly convergent
and the rostral suture more forwardly convex, giving a more
parabolic or V-shaped outline to the anterior margin of the
cranidium. By contrast, the rostral suture of Wenndorfia is
transverse or weakly convex forwards. The anterior branches of
the facial sutures tend to be less strongly convergent posterior-
ly, abruptly curved medially and more strongly convergent
anteriorly, giving the anterior margin of the cranidium a more
rounded, U-shaped outline.

Reed (1918) suggested that Dipleura was derived from
Digonus. More recent phylogenies are in accord in deriving
Dipleura directly from Trimerus, although there is disagree-
ment in the chronology of this transition. Sdzuy (1957: fig. 3)
considered Dipleura to have originated from Trimerus at the
Siluro-Devonian boundary. Tomczykowa (1975) established an
earlier origin for Dipleura, and suggested two species from the
upper Ludlow of Poland, Dipleura praecox Tomczykowa, 1975
and Trimerus permutus Tomczykowa, 1978 from the immedi-
ately underlying beds, to be closely related and to represent a
transitional li nk between the genera. An earlier origin for
Dipleura is indicated by its occurrence in lower Ludlow strata
of Victoria, supporting Wenndorf’s (1990: fig. 6) suggestion of
a Wenlock origin for the genus.

Dipleura is presumably derived from Lower Silurian

30

Andrew C. Sandford

Trimerus. Lower Silurian Trimerus are variably assigned in this
work to T. ( Trimerus ) or to T. ( Ramiotis ). T. ( Trimerus ) is
characterised by a suite of distinctive cephalic and pygidial
features, notably a glabellar outline markedly expanded across
LI -LI (tr.), raised glabellar profile, the strongly-defined
glabellar lobation, L1-L2 muscle scars, sagittal ridge, exsa-
gittal furrows and paraglabellar areas, the long and weakly con-
cave (tr.) preglabellar field, and the produced pygidial tip. In
the absence of most of these features species assigned to
T. ( Ramiotis ) more closely resemble Dipleura. Llandovery
species of T. ( Ramiotis ) exhibit features that show a strong
resemblance to those typical of Dipleura, sharing trapezoid
glabellar outlines, shorter preglabellar fields and marked
contrast between the depth of the ring furrows and pleural
furrows, with the latter very shallow to almost effaced.

Sdzuy (1957) interpreted Homalonotus ( Trimerus ) mongo-
licus Tchemycheva, 1937 from the Upper Silurian of Mongolia
as an intermediate form between Dipleura and Trimerus. Sdzuy
emphasised the posterior eye position, the rounded pygidial
outline and the marked contrast between the depth of the ring
furrows and almost effaced pleural furrows to support his inter-
pretation. The significance of these characters is overstated by
Sduzy. The markedly weak pleural furrows and rounded
pygidial outline of mongolicus emphasised by Sdzuy are not
features unique to Dipleura and occur amongst species of
T. ( Ramiotis ) and T. ( Edgillia ). The eyes of mongolicus are
clearly placed directly opposite the glabellar midlength
(Tchemycheva, 1937: pi. 1 fig. 8). The rounded pygidial outline
emphasised by Sdzuy is contradicted by Tchemycheva’ s
description of the pygidium as “triangular, usually elongated,
terminates in a thick spine ” (Tchemycheva, 1937: 25). In
strong contrast to Dipleura, the species exhibits a very long
preglabellar field (0.3 cranidial length) and the anterior branch-
es of the facial sutures are relatively weakly convergent (60°).
Tchemycheva’ s description of other features including a sub-
quadrate, weakly tapering glabellar outline, an evenly vaulted
glabellar profile, weak SI and indistinct S2 and S3, 13
pygidial axial rings, shallow pygidial pleural furrows, the
absence of a postaxial ridge ( “rhachis falling short of poster-
ior margin”) and the pygidial proportions (length 0.92 width)
indicate assignment to T. (Edgillia).

Dipleura garratti sp. nov.

Figure 14

Homalonotus sp. — Chapman, 1908: 220.

Type material. Holotype NMV P308644 (pygidium) from PL6615,
Eden Park, Victoria (Fig. 14.13). Paratypes NMV P308638, NMV
P308641 (cranidia), NMV P308639, NMV P308642, NMV P308645
(cephala), NMV P308643 (librigena), NMV P308637, NMV P308640,
NMV P308646 (pygidia) from PL6615. Paratypes NMV P308635-6
(cephalothoraxes) , NMV P308649, NMV P308651, NMV P308663,
(cephala), NMV P308657 (cranidium) from PL6614, Eden Park. NMV
P308648 from “Whittlesea”, Victoria. For localities see Fig. 11.

Registered material. 47 specimens: 4 cephalothoraxes, 8 cephala, 17
cranidia, 2 librigenae, 2 thoracic segments, 14 pygidia. NMV
P3045 1 3-P3 045 1 5 , NMV P304572, P304573, NMV

P308633-P308636, NMV P308649-P308657, NMV P308673 from
PL6614. NMV P308637-P308647, NMV P308659-P308672 from
PL6615. NMV P308658 from PL6625, Wandong, Victoria. NMV
P308648 from “Whittlesea”. Unregistered specimens from PL1793,
Clonbinane and Kenley locality 14c, Upper Plenty. For localities see
Fig. 11.

Stratigraphic distribution. As for Homalonotus williamsi.

Derivation of name. For Michael J. Garratt, for his contribution
to Victorian palaeontology and stratigraphy.

Diagnosis. Glabella trapezoid, length 1.05 times preoccipital
glabellar width, sides straight and converging at about 25°,
anterior margin well defined, very broadly rounded to trans-
verse. Length (sag.) of preglabellar field 0.15-0.18 times cran-
idial length. Palpebral lobe placed with midline opposite 0.47
times glabellar length/0.38 times cranidial length. Anterior
branches of facial suture angular, subparallel to axial furrows to
a point opposite 0.75 glabellar length, anteriorly converging at
about 80°. Rostral suture broadly curved. Ventral surface of
rostral plate with length about equal to width, flat, connective
sutures angular, anterior section converging at 40 degrees, pos-
terior section at 80°. Pygidium triangular, length equal to width,
sides straight and converging at 65°, tip acutely angular.
Pygidial axis with width 0.5 times pygidial width, 12 axial
rings, ring furrows moderately impressed, axis moderately
swollen posteriorly, continuous with wide but poorly defined
postaxial ridge. Axial furrows straight and tapering at about
33°, weakly impressed to indistinct. Pleural furrows weakly
impressed to indistinct. 6 pleural ribs, rib-ring medially offset
at second rib.

Description. Exoskeleton small (maximum length estimated 8 cm
from NMV P308644), occipital and pygidial convexity (tr.) moderate.
Dorsal exoskeleton finely granulose.

Cephalon with width about 1.6 times length, with semielliptic out-
line, sides moderately convex. Cranidial width about 1.64 times length.

Figure 14. Dipleura garratti sp. nov. 1, paratype NMV P308638, cranidium, dorsal view x 3.0 (internal mould) from PL6615. 2, paratype NMV
P308645, cephalon, dorsal view x 3.0 (latex cast) from PL6615. 3, paratype NMV P308646, pygidium, dorsal view x 3.8 (internal mould) from
PL6615. 4a, paratype NMV P308663, cephalon, ventral view (doublure) x 4.1 (latex cast) from PL6614. 4b, same, enlargement of rostral plate
x 15. 5, paratype NMV P308641, cranidium, dorsal view x 3.0 (internal mould) from PL6615. 6, paratype NMV P308642, cephalon, dorsal view
x 2.2 (internal mould) from PL6615. 7, paratype NMV P308643, librigena, ventral view (doublure) x 2.6 (latex mould) from PL6615. 8, paratype
NMV P308657, cranidium, dorsal view x 1.9 (internal mould) from PL6614. 9, paratype NMV P308649, cephalon, dorsal view x 2.0 (internal
mould) from PL6614. 10a, paratype NMV P308635, cephalothorax, dorsal view of cephalon x 2.2 (internal mould) from PL6614. 10b, same, dor-
sal view of thorax x 2.0. 11, paratype NMV P308639, cephalon, dorsal view x 1.8 (internal mould) from PL6615. 12, paratype NMV P308640,
pygidium, dorsal view x 3.5 (internal mould) from PL6615. 13a, holotype NMV P308644, pygidium, dorsal view x 2.1 (internal mould) from
PL6615. 13b, same, posterior view. 13c, same, lateral view x 2.8. 14, paratype NMV P308648, cephalon, oblique view x 3.0 (latex cast) from
PL6614. 15, paratype NMV P308637, pygidium, dorsal view x 3.5 (internal mould) from PL6615. 16, paratype NMV P308636, cephalothorax,
lateral view x 3.0 (internal mould) from PL6614. 17, paratype NMV P308651, cephalon, dorsal view x 3.3 (internal mould) from PL6614.

Homalonotid trilobites from the Silurian and Lower Devonian

31

32

Andrew C. Sandford

Glabellar length about 0.8 times cranidial length. Occipital ring 0.12
times glabellar length, slightly wider medially. Occipital furrow deeply
impressed, with weak forward flexure medially. Glabellar lobation
extremely weak to indistinct, best seen on NMV P308638 as very
shallow depression at adaxial end of SI placed opposite 0.3 times
glabellar length. Paraglabellar area very weakly defined. Length
(exsag.) of posterior border equal to occipital length adaxially, length-
ening slightly abaxially. Posterior border furrow transverse adaxially,
curving gently forwards abaxially, very wide, moderately impressed,
terminating distally. Postocular fixigenal area very short, length
(exsag.) 0.15 times cranidial length. Palpebral lobes placed remotely
(6-6 1.65 times preoccipital glabellar width). Palpebral lobe length
(exsag.) 0.15 times cranidial length, palpebral furrow indistinct.
Preocular fixigenal area of moderate width, 0.18 5-6, narrowing
slightly anteriorly, eye ridges very weakly defined. Librigena without
distinct border furrow or lateral border. Dorsal surface of rostral plate
very short (sag.), crescentic in outline. Ventral surface of rostral plate
kite-shaped, posterior width 0.2 times maximum width. Hypostomal
suture extremely weakly curved.

Thorax with thirteen segments. Axial furrows extremely shallow,
expressed as diagonally directed furrows on each segment, each
meeting posterior margin at axial articulating process on internal
mould. Pleural furrows wide and deep across axis, narrower (exsag.)
and deeper across pleural field.

Pygidial border furrow and border poorly defined. In posterior view
posterior margin of pygidium horizontal. In lateral view dorsal profile
evenly inclined, interrap ted by swelling of terminal piece.

Discussion. The assignment of this species to Dipleura is indi-
cated by the course of the facial sutures (anterior branches con-
verging at 90°), the posterior position of the eye and the almost
effaced pygidial axial furrows and pleural furrows. The short
preglabellar field and indistinct glabellar lobation are in accord
with this assignment. D. garratti is the earliest representative of
the genus. A number of differences with later Dipleura can be
interpreted as reflecting the closer affinities of garratti with
Trimerus, particularly its triangular pygidial outline and its pos-
teriorly raised axis that is continuous with a wide postaxial
ridge (Fig. 14.12).

In many features Dipleura garratti is most closely com-
parable to the German upper Pragian-lower Emsian
D. laevicauda, sharing a moderately tapered glabellar outline,
more elongate pygidial proportions and a relatively wide
pygidial axis. The course of the cephalic sutures is most like
that of the Bolivian Givetian D. boliviensis. Originally
described as a subspecies of D. dekayi, the relatively longer
cephalic proportions, more tapering glabella, more anteriorly
and less remotely placed eyes are significant in regarding
boliviensis as an independent species.

Environmental notes. Dipleura garratti occurs in a trilobite
fauna dominated by proetids and dalmanitids, with Homalon-
otus williamsi, aulacopleurids, odontopleurids and phacopids in
very low abundance. Although known from various localities
between Clonbinane and Eden Park, the fauna is well repre-
sented at two richly fossiliferous localities in the Macropleura
band at Eden Park, a horizon characterised by an abundance of
the large, thick-shelled brachiopod M. densilineata. At PL6615,
dalmanitids (relative abundance 50%) are more abundant than
proetids (relative abundance 21%), whereas at PL6614 the
proetids are dominant (relative abundance 55%) over dalman-

itids (relative abundance 26%). The relative abundances of
garratti and williamsi are similar at both localities (17-19% and
2% respectively).

The taphonomy and facies of Dipleura garratti differs
markedly between PL6614 and PL6615. At PL6615, 87% are
isolated tergites and the remainder are cephala. With the excep-
tion of the cephalon of Homalonotus williamsi all other
trilobites associated with garratti are represented by isolated
tergites, with the proportion of broken specimens 16%. The
lithology is best described as a bioclastic coquina in a siltstone
matrix. Assignment to shallow taphofacies TII is in accord with
Garratt’s (1983) assignment of the brachiopod fauna to the
shallow-water Notoconchidium Community (BA2). A moderate
energy environment at depths around normal wave base is
indicated. Slightly deeper conditions are indicated by the
taphonomy and lithofacies at PL6614, where 21% of specimens
of garratti are cephala and 21% are cephalothoraxes. The pro-
portion of broken specimens (9%) is lower than at PL6615. The
lithology at PL6614 is a poorly bedded micaceous siltstone,
and although bioclasts are extremely abundant they have not
been winnowed to form a coquina. The preservation suggests
an environment at depths below normal wave base.

Parahomalonotus Reed, 1918

Type species. Homalonotus gervillei De Verneuil, 1850. From the
Pragian of France, Turkey, Spain, Morocco, Romania and Turkey, by
original designation.

Other species included. Parahomalonotus diablintianus Morzadec,
1976, Homalonotus vialai Gosselet, 1912 (in Gosselet et al.), P. sp. A
(=P. gervillei in Haas, 1968), P. sp. B (=P. aff. gervillei in Wenndorf,
1990).

Other species tentatively included. Digonus sp. cf. E in Morzadec,
1986.

Range. Lower Devonian.

Revised diagnosis. Glabella moderately to strongly convex
(tr. sect.) and narrow, with length 1.2- 1.6 times width. Axial
furrows moderately to deeply impressed. Lobation distinct,
S1-S3 moderately to deeply impressed. Pygidial axis narrow
(0.35-0.4 times pygidial width anteriorly), weakly tapering
(-25-30°), with moderate to strong convexity independent of
the pleural convexity, raised posteriorly, continuous with wide
postaxial ridge reaching posterior margin, pygidial tip with
small point or short slender spine.

Discussion. The restricted diagnosis of Parahomalonotus
defines a tight group distinct from Wenndorfia, to which many
species previously assigned to Parahomalonotus have been
assigned. Species assigned to Parahomalonotus also share
weak glabellar tapering (0-18°), a preglabellar field of mod-
erate (0.2) to short (0.05) length, eyes placed posteriorly
(opposite 0.35-0.5 cranidial length), subparallel to moderately
convergent anterior branches of facial suture, a transverse
rostral suture, an obtusely angled (130-150°) to rounded
pygidial tip and equally well defined axial rings and pleural
ribs.

Pygidial morphology of Parahomalonotus is distinct from
that of Wenndorfia and is conservative, with the exception of

Homalonotid trilobites from the Silurian and Lower Devonian

33

P. diablintianus in which pygidial ring and pleural furrows are
relatively shallow and the pygidial outline distinctly rounded,
hi cephalic features, the younger late Pragian-Emsian forms
(P. sp. A, P. gervillei ) differ from earlier species in their
stronger glabellar convexity and lobation, and greatly reduced
preglabellar fields. Of the earlier taxa, P. vialai shows the
closest affinities with the type species and represents an inter-
mediate morphology in which glabellar furrows and lobation
are more moderately expressed.

To the species Parahomalonotus sp. A illustrated by Haas
(1968: pi. 30 figs 1-4 as P. gervillei ) from the Emsian of Turkey
can be added at least one of the cranidia (pi. 29 fig. 26)
described as Dipleura fornix, differing from other specimens of
fornix in having a transverse glabellar anterior margin and
straight rather than concave glabellar sides.

Trimerus Green, 1832

Type species. Trimerus delphinocephalus Green, 1832 from the
Wenlock Rochester Shale, New York State, by monotypy.

Subgenera included. Trimerus ( Trimerus ) Green, 1832, T. (Ramiotis)
subgen. nov., T. ( Edgillia ) subgen. nov.

Range. Llandovery-Lochkovian.

Revised diagnosis. Cephalon triangular to rounded pentagonal
in outline, length 0.6-0.7 times width, anterior margin entire,
trilobed or tricusped. Preglabellar field of moderate length to
very long, 0.16-0.35 times cranidial length, flat or weakly con-
cave (tr.) medially. Glabella generally with distinct lobation and
median indentation of anterior margin. Eyes placed forwardly,
with midline of palpebral lobes opposite 0.5-0.75 glabellar
length (0.38-0.5 cranidial length) and medially on genae (6-5
1.3- 1.7 times preoccipital glabellar width). Anterior branch of
facial suture more or less straight and moderately convergent
(45-60°) between eye and a point opposite midlength of
preglabellar field. Rostral suture on dorsal surface, transverse
or arching forwards evenly or with a median angle.
Paraglabellar areas large. Ventral surface of rostral plate flat or
weakly convex, without process. Thoracic axial furrows poorly
defined. Pygidium with axis of moderate width (0.3-0.6 times
pygidial width), not reaching posterior margin, axial furrows
moderately impressed, axial ring and pleural furrows distinct
but of variable depth, 6-12 rings, 5-10 ribs.

Discussion. The revised diagnosis incorporates and quantifies
most features listed in more recent diagnoses of Trimerus. New
characters include the relatively forward position of the eye, the
straight course of the anterior branch of the facial suture, and
the moderate axial width. Early diagnoses, such as Salter’s
(1865), predominantly list characters of a very general nature.

Three species groups are recognised in this work and
defined as the subgenera Trimerus (Trimerus), T. (Ramiotis)
and T. (Edgillia). Previous diagnoses of Trimerus emphasise
the well-defined glabellar lobation, triangular pygidial outline
and acuminate pygidial tip (i.e. a mucro) exhibited by the type
species and shared with closely related species including T. (T.)
cylindricus, T. (T.) vomer (Chapman, 1912) and T. (T.) johan-
nis. These features and a suite of other distinctive glabellar
features are considered here to be diagnostic only of the typical

subgenus T. (Trimerus). The forwardly arcuate course of the
rostral suture and the short length (sag.) of the dorsal section of
the rostral plate noted in previous diagnoses of Trimerus
(Tomczykowa, 1975, Thomas in Curtis and Lane, 1998) is
considered here to be only of specific significance for
T. (T.) delphinocephalus.

A second group comprising other Silurian species of
Trimerus can be recognised, and is described in this work as
T. (Ramiotis). Members of this group lack the produced pygidi-
al tip and distinctive glabellar features of T. (Trimerus). The
group is typified by a new upper Llandovery species from
Victoria, T. (R.) rickardsi. The species assigned to this group
share a suite of characters including less acute to obtusely
angled pygidial tips lacking a mucro, and an elongate,
weakly tapering, more or less straight-sided glabella with
weakly defined lobation. Tomczykowa (1975) included a slight
degree of tapering of the glabella in her diagnosis of Trimerus,
but this character is peculiar to T. (Ramiotis). The degree of
glabellar tapering in Trimerus varies between the strongly
tapered (-55°) and posteriorly expanded morphologies of
T. (Trimerus), moderately tapered trapezoid morphologies
of T. (Ramiotis), and very weakly tapered (<15°) subquadrate
morphologies of T. (Edgillia), the latter erected in this work
for a group of Upper Silurian-Lower Devonian species.
T. (Ramiotis) is further distinguished from T. (Trimerus) by a
tendency towards a shorter preglabellar field, shorter pygidial
proportions and more weakly defined pygidial segmentation.
Trimerus (Edgillia) can be distinguished from the Silurian sub-
genera by a distinctive morphology typified by the Victorian
T. (E.) kinglakensis (Gill, 1949). The species assigned share a
very weakly tapered, subquadrate glabellar outline, weakly
defined glabellar lobation, and lack the raised postaxial ridge
present on most Silurian representatives of Trimerus.

Sdzuy (1959) considered Trimerus to comprise also the sub-
genus Dipleura. The revised diagnosis of Dipleura is in accord
with Tomczykowa (1975) and Wenndorf (1990) in recognising
Dipleura and Trimerus as independent genera. Sdzuy’s diag-
nosis of T. (Trimerus) emphasises differences from Dipleura,
listing the longer cephalic proportions, a more tapering gla-
bella, distinct glabellar lobation and paraglabellar areas, a for-
wardly convex rostral suture, an acuminate pygidial tip, and
more distinct pygidial segmentation. Diagnoses of Trimerus by
Thomas (in Curtis and Lane, 1998) and Tomczykowa (1975)
closely follow Sdzuy’s brief subgeneric diagnosis, but incor-
porate only some of the features listed by him. Importantly,
both Thomas and Tomczykowa omitted the morphology of the
rostral plate as a diagnostic character. Holloway and Neil
(1982) suggested the significance of homalonotid coaptative
morphologies, and in accord with this view the absence of a
rostral process is reinstated in the diagnosis. In emphasising
this feature and in the presence of other differences, a number
of Lower Devonian species previously assigned to Trimerus are
excluded, including Homalonotus noticus from South America
and South Africa), Burmeisteria (Digonus) accraensis from
Ghana and Trimerus novus Tomczykowa, 1975 from Poland.

Edgecombe and Fortey (2000) reassigned Homalonotus
linares Salter, 1861 from the Pffdolf of Bolivia to Trimerus.
The species exhibits a number of features that are not com-

34

Andrew C. Sandford

patible with this assignment. The axial ring count (14-16) is
higher than any species assigned to Trimerus (ranging 6-12),
the width of the axis (up to 0.7 width) is greater than in any
species assigned to Trimerus (ranging 0.3-0.6 width), the
pygidium is longer (length/width ratio 1 . 1-1 .2) than all species
of Trimerus (length/width ranging 0. 6-1.0) except for
T. ( Trimerus ) cylindricus Salter (1865), and the cephalic pro-
portions are longer (“ transverse width slightly exceeding
length Edgecombe and Fortey, 2000: 332) than any species of
Trimerus (length/width ranging 0.6-0.7), complementing its
elongate pygidial proportions. These features are more com-
patible with assignment to Burmeisteria. The type species,
B. herschelii exhibits comparably high pygidial segmentation
(16-17 axial rings, 9-11 pleural ribs), elongate pygidial pro-
portions and a wide pygidial axis. Although the course of the
rostral suture and the morphology of the rostral plate (including
the presence of a ventral process) for B. linares remains uncer-
tain, there is a suggestion of moderate convexity of the rostral
plate in one of the cranidia illustrated by Edgecombe and
Fortey (2000: pi. 2 fig. 16).

In addition to the several species reassigned to Burmeisteria
and Dig onus (discussed above), a considerable number of
species assigned to Trimerus by Tomczykowa (1975) and
Wenndorf (1990) are assigned to other genera. T. lilydalensis is
assigned below to Wenndorfia. Pygidia from the upper Pragian
of Morocco, identified by Schraut (2000) as T. sp. cf. crassi-
cauda are too fragmentary for confident assignment to
Trimerus , although the shallower axial ring and pleural furrows
preclude assignment to the German species. The relationships
of a number of poorly documented taxa previously assigned to
Trimerus are uncertain, including Homalonotus acuminatus
Tromelin and Lebesconte, 1876 and the French H. leheri
Barrois, 1886.

Trimerus ( Trimerus ) Green, 1832

Type species. Trimerus delphinocephalus Green, 1832, from the
Wenlock Rochester Shale, New York State, by monotypy.

Other species included. Homalonotus ( Trimerus ) cylindricus Salter,
1865, T. (T.) flexuosus Benedetto and Martel (in Baldis et al., 1976),
H. harrisoni McCoy, 1876, H. (T.) johannis Salter, 1865, H. vomer
Chapman, 1912, T. (T.) sp. A in Alberti (1970), T. sp. in Owens (1994).

Range. Wenlock-Ludlow, Pfldoli?

Diagnosis. Glabella moderately to strongly expanded across
LI -LI (tr.), strongly raised, markedly narrower (tr.) anteriorly
than posteriorly (sides tapering at 33-55°, width opposite S3
less than 0.65 times LI -LI). SI moderately to strongly
expressed, S2 and S3 distinct or fused with SI to form a shal-
low exsagittal depression. LI and L2 with low ovoid swellings.
Sagittal ridge of glabella well defined. Preglabellar field long to
very long (0.22-0.35 times cranidial length), distinctly concave
(tr. sect.). Pygidial length equal to or greater than width.
Pygidial ring furrows and pleural furrows of similar depth,
10-12 axial rings, 7-9 ribs. Pygidium with acutely produced tip
or with short, spine-like process.

Discussion. The type species Trimerus delphinocephalus
belongs to a distinct species group within Trimerus, restricted
in distribution to the mid Wenlock-lower Ludlow interval. The

group is easily recognised in having distinctive glabellar
features, particularly the glabella with an outline markedly
expanded across Ll-Ll (tr.), raised profile, distinct lobation,
swellings on LI and L2, and the sagittal ridge. In comparison
to other members of Trimerus, these species also have more
elongate preglabellar fields, more elongate and more highly
segmented pygidia, and bear a short spine or acute process on
the pygidial terminus. The species assigned are easily distin-
guished from other Trimerus, in which the characters listed are
only occasionally or weakly expressed.

The characteristic cephalic features of Trimerus ( Trimerus )
are expressed most strongly in T. (T.) johannis from the upper
Wenlock of England and T. (T.) vomer from the basal
Ludlow in Victoria. These species are interpreted as the most
highly derived of those assigned. Populations of T. (T.)
delphinocephalus show wide morphological variability and the
cephalic features characteristic of the subgenus are variably
expressed, although they are clearly present in specimens fig-
ured by Whittington (1993: figs 1, 2). Pygidia of delphino-
cephalus differ from those of johannis and vomer in having
shallower ring furrows and pleural furrows, and a short spine-
like process posteriorly. In outline, the depth of the pygidial
furrowing and presence of a posterior spine a single pygidium
documented from the Upper Silurian of Morocco (Alberti,
1970, Schraut, 2000) closely resembles pygidia of
delphinocephalus and is also assigned to the subgenus.

Trimerus ( Trimerus ) flexuosus from the Wenlock-Ludlow?
of Argentina is poorly known but is clearly attributable to
T. (Trimerus). Benedetto and Martel (in Baldis et al., 1976)
describe the species as having a raised glabella with distinct
SI -S3, subcircular-ovate swellings on LI, and strongly defined
paraglabellar areas, features characteristic of the subgenus. The
pygidium closely resembles that of T. (T.) sp. (in Alberti, 1970)
from Morocco in outline, in the depth of the pygidial furrowing
and in the presence of a posterior spine. The rostral suture is
convex, as in the type species.

An incomplete cranidium figured as Trimerus sp. from the
upper Wenlock Brinkmarsh Beds of England (Owens, 1994: pi.
2 fig. J) can be assigned to T. (Trimerus). In outline and
height the glabella is not unlike that of T. (T.) johannis from the
nearby area, to which it may belong.

The anterior margin of the cephalon is variably expressed in
Trimerus (Trimerus). In T. (T.) vomer, the angle of convergence
of the sides of the cephalon increases abruptly opposite the
antero-lateral comers of the cranidium, giving the cephalon an
irregular pentagonal outline. In T. (T.) johannis (and possibly
T. (T.) flexuosus) the anterior margin of the cephalon is tri-
cuspate, with the sides of the cephalon invaginated opposite the
connective suture. The weakly trilobate anterior margin of the
cephalon of T. (T.) delphinocephalus is intermediate between
these morphologies.

Trimerus (Trimerus) harrisoni (McCoy, 1876)

Figures 5B, 19.7, 19.9, 19.11

Homalonotus harrisoni McCoy, 1876: 19, pi. 23 fig. 11.

Trimerus harrisoni. — Gill, 1949: 65, text-fig. 1A. — Sandford, 2000:
189, figs. 17A-E.

Homalonotid trilobites from the Silurian and Lower Devonian

Remarks. I recently provided a comprehensive synonymy,
revised diagnosis and description for Trimerus ( Trimerus )
harrisoni (see Sandford, 2000). No new material has been
obtained. Poor preservation of all known cranidia obscures
many features of the cephalon pertinent to its subgeneric
assignment. The glabella is not strongly raised, although this
is true also of the type species Trimerus {Trimerus) del-
phinocephalus. The glabella tapers very strongly forwards,
although whether bell shaped or trapezoid in outline is not clear
as the best-preserved specimen is somewhat crushed. The poor-
ly known pygidia of harrisoni resemble those of the type
species in the depth and relative depth of the pleural and ring
furrows, although differ in having a prominent postaxial ridge
and possibly in lacking a posterior spine. In respect to these
latter differences, the pygidial morphology of harrisoni is not
incompatible with T. ( Ramiotis ). However, the strong tapering
of the glabella and exceptional length of the preglabellar field
are emphasised here in assigning the species to T. {Trimerus).

Trimerus {Trimerus) vomer (Chapman, 1912)

Figure 15

Homalonotus vomer Chapman, 1912: 298, pi. 62 figs 2, 3, pi. 63 fig.
2, non pi. 63 fig. 1 (= Trimerus {Ramiotis) otisi sp. nov.)

Homalonotus {Trimerus) vomer . — Reed, 1918: 323.

Trimerus vomer . — Gill, 1949: 65, text-fig. 1C non IB {=Trimerus
{Ramiotis) otisi sp. nov.). — Tomczykowa, 1975: 11. — Wenndorf,
1990: 16.— Schraut, 2000: 383.

Type material. Holotype NMV PI 2301 (cephalon and displaced thorax,
figured Chapman, 1912, pi. 62 fig. 1, 2, Gill, 1949a, text-fig. 1C, Fig.
15.4 herein) from “Wandong”, Victoria. Paratype NMV P12302
(thoracopygon, figured Chapman, 1912, pi. 63 fig. 2 from “Wandong”.
Paratype NMV P12303 (cephalon, figured Chapman, 1912, pi. 63
fig. 1, Gill, 1949a, text-fig. IB) from “Wandong”. For localities see
Fig. 11.

Registered material. 55 specimens. NMV P455, NMV P529, NMV
P16415, NMV P136623-P136627, NMV P136629-P136633, NMV
P137158, NMV P137291, NMV P137910 from “Wandong”. NMV
P 1 366 1 2-P 1 36622 , NMV P136628, NMV P136680, NMV P137120,
P137121, NMV P137126-P137137 from PL286, Williams locality
F22, Kilmore East, Victoria. NMV P136634-P 136636 from “Kilmore
East-Sunday Creek Road”, Kilmore East. NMV P136637 from
“Langford Park”, Kilmore East. NMV PI 36846, NMV PI 37887 from
“Kilmore”, Victoria. NMV P137122-P137124, NMV P137144, NMV
PI 38649 from “Kilmore- Wandong”. NMV P137144 from PL868,
Kilmore East. Yan Yean Formation. NMV P136638 from “Heathcote”,
Victoria. For localities see Fig. 11.

Revised diagnosis. Cranidial width 1.5 times length. Glabella
strongly raised, length equal to width, strongly bell shaped in
outline, much narrower anteriorly than posteriorly, anterior
margin well defined, with deep medial indentation. SI -S3 dis-
tinct, SI with deeply impressed apodeme at adaxial end.
Paraglabellar area very strongly defined. Preglabellar field very
long, 0.3 times cranidial length, weakly concave (tr. sect.).
Palpebral lobes placed opposite 0.5 cranidial length (0.7 glabel-
lar length). Weak but distinct eye ridges. Anterior branches of
the facial suture straight, converging at about 55° to a point
opposite midlength of preglabellar field. Rostral suture trans-
verse. Dorsal section of rostral plate triangular, long, 0.1

35

cephalic length. Ventral section of rostral plate elongate, width
0.85 times length, connective sutures straight and converging
posteriorly at 35°. Pygidium triangular, length equalling width,
with broad based, acutely pointed tip. Axial furrows moderate-
ly to deeply impressed. Axial width (measured across second
ring) 0.37 times pygidial width. Axis raised, markedly swollen
posteriorly. Wide postaxial ridge. 10-12 axial rings. 8 pleural
ribs with nineth rib reduced or absent. Pygidial pleural and ring
furrows deep, of equal depth. Rib-ring medial offset at fifth rib.

Description. Exoskeleton maximum length estimated 12 cm long.
Exoskeleton granulate, more densely in the alae, finely tuberculate tho-
racic segments.

Cephalon triangular, length 0.8 width, in transverse and sagittal sec-
tion posteriorly convex, anteriorly concave, lateral margins converging
at 70-80°, genal angles and anterior tip rounded. Glabella 0.6 cephalic
length, strongly bell shaped, narrowing markedly opposite palpebral
area, posterior width equal to length and twice anterior width, in
section (tr., sag.) weakly convex posteriorly, less so anteriorly.
Occipital ring transverse, lower than glabella, 0.1 glabellar length,
slightly wider at medial apex, in transverse section arched at medial
apex, sloping at a uniform gradient abaxially, not interrupted by axial
furrow and thus continuous with posterior border. Occipital furrow
deeply impressed, strongly deflected forwards medially and less so
abaxially, wider at medial apex. SI a wide shallow furrow directed
inwards backwards between 0.2 and 0.4 preoccipital glabellar width,
deeper at extremities. LI weakly defined as an independently convex,
triangular lobe, widest abaxially, maximum exsagittal length 0.3
glabellar length. S2 and S3 weakly defined as wide shallow depres-
sions not connected with axial furrows. L2 and L3 undefined. Frontal
lobe impressed medially by a short (sag.) wide notch. Axial furrow
developed posteriorly as large semicircular alae as long as and placed
opposite LI. Anteriorly axial furrow very wide, deepening opposite
antero-lateral comer of glabella. Preglabellar furrow indistinct, defined
as a change in height from the frontal lobe to the frontal area. Frontal
area long (sag.), 0.4 glabellar length. Medial area increasingly concave
anteriorly, margins increasingly convex posteriorly in transverse
section. Genae inflated. Fixigenae wide (tr.), approximately 0.5 pre-
occipital glabellar width at midline. Palpebral area wide and convex
(tr.), palpebral lobe inclined at 45°, semicircular, 0.25 glabellar length
(sag.), placed anterior of and adjacent to glabellar transverse midline,
weak eye-ridge directed inwards forwards to a point opposite S3.
Anterior to palpebral area fixigenae sloping down to frontal area, not
extending anteriorly as far as glabella. Posterior to palpebral lobe
fixigenae wide (exsag.), 0.33 glabellar length, narrowing abaxially,
strongly convex. Posterior border furrow wide, shallowing and curving
forwards abaxially. Posterior border lower than genal area, increasing-
ly convex (exsag.) and widening to twice occipital ring width (sag.)
abaxially. Genal angle broadly rounded. Anterior facial suture con-
verging forwards at about 60°, meeting connective suture very close to
margin at a point opposite 2/3 sagittal length of frontal area (measured
from glabella). Connective sutures short on dorsal surface, diverging
forwards at 90°. Rostral suture transverse. Posterior branch of facial
suture transverse adaxially, curving backwards abaxially, crossing
margin just anterior of genal angle. Librigenae triangular, convex,
steep. Eye small, raised above genal surface. Lateral border furrow
defined as an angular change in slope, less distinct toward genal angle.
Lateral border narrowing anteriorly by a factor of four from genal
angle, flat and horizontal. Lateral border and furrow indistinct anterior
to genae. Anterior facial sutures converging at 60°, close to margin and
curving inwards anteriorly, meeting connective suture on a transverse
line 0.3 sagittal length of frontal area from anterior tip. Connective
suture short on dorsal surface, diverging at 90°. Ventral portion of

36

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

rostral plate flat, elongate pentangular, long (sag.), 0.4 cranidial length
(extending to anterior margin of glabella), maximum width 0.8 length,
placed at 0.75 rostral length. Connective sutures straight, converging
posteriorly at 35°, posterior margin transverse, 0.4 maximum width.
Dorsal portion of rostral plate triangular to weakly crescentic, flat, very
short (sag.) length 0.2 width between posterolateral corners and 0.2
ventral length. Anterior margin straight abaxially, each side converging
at 110°, medially rounded. Rostral suture convergent at 170° laterally
(to one third maximum width), transverse medially. Connective sutures
short (exsag.) apparently marginal between posterolateral comers of
dorsal portion and anterolateral corners of ventral portion. Doublure
posterior margin transverse, as wide as rostral plate adjacent to
connective suture but narrowing adaxially. Adjacent to lateral margin
doublure concave in section such that it closely parallels the dorsal
exoskeleton.

Thorax 1 1 segments. Axis cigar shaped, weakly convex (tr.), wide,
0.7 (max.) thoracic width in dorsal view. Pleural field narrow in dorsal
view, 0.15 thoracic width, convex (tr.), flexed to subvertical, twice as
long abaxial of flexure than adaxial. Axial rings convex (sag.), trans-
verse, wider medially than abaxially. Pleural furrow continues onto
rings, deep slot-like, defining anterior band wider abaxially. Axis dis-
tinguished from pleural field by independent convexity and by a
depressed area in the posterior edge of the pleurae. Pleural furrow
divides narrow anterior band from posterior band twice as wide,
shallows towards tip. Abaxially of flexure pleurae widen slightly,
almost wholly occupied by articulating facet, which has a rounded tip.

Pygidial proportions as for cephalon. Trilobation distinct. Anteriorly
axis as wide as pleurae, tapering uniformly, 0.8 pygidial length, in
transverse section axis weakly convex anteriorly to strongly convex
posteriorly. In sagittal section axis concave anteriorly, posteriorly with
long prominent swelling and strongly concave. 9-10 distinct rings,
swelling 0.25 axial length and very feintly ringed. Axial rings very
weakly convex (sag.) and weakly convex-forwards. Anterior ring
furrow higher than others, second ring with pseudo-articulating half-
ring. Rings 1-7 of u ni form width, posterior rings (8+) as narrow ridges
Posterior of axis border strongly arched (tr. sect.) and high. Axial
furrow shallow and wide. Pleural field uniformly convex. Pleural fur-
rows distinct. 9 ribs, wider than rings, and widening abaxially, flat
(exsag.). Interpleural furrows not distinct. Border narrow, concave,
widening posteriorly.

Remarks. Many of the characters listed as diagnostic of
Trimerus ( Trimerus ) are strongly expressed in T. (T.) vomer,
including the definition of SI and LI and L2 swellings, the
paraglabellar area, the length of the preglabellar field and the
bell-shape of the glabella. T. ( T .) vomer also displays a number
of unusual characters including distinct eye ridges and deep S 1
apodemes, and further differs from other members of Trimerus

37

{Trimerus) in having a particularly long rostral plate (dorsally),
and very forwardly placed eyes. The deep SI apodemes are one
of the most distinctive features of vomer. The orientation and
position of these apodemes appears to be somewhat variable,
however, being transverse on some specimens, diagonal on
others, and sagittal on others. These differences may well be
attributable to deformation, as is suggested by the correlation of
glabellar proportions with apodeme orientation. Specimens
with tectonically shortened glabellae (L:W~0.8) have trans-
verse apodemes, those with tectonically elongated glabellae
(L:W~1.1) have sagittally directed apodemes. The prede-
formational orientation was probably diagonal, as in the
holotype.

Although with many unique characters, Trimerus ( Trimerus )
vomer is most closely comparable to T. (T.) johannis from the
Wenlock of Wales. These species share a transverse rostral
suture, a markedly raised and very strongly expanded (tr.)
glabella (more exaggerated in vomer), very distinct and large
paraglabellar areas and a distinctly concave preglabellar field.
The deep ring furrows and pleural furrows, the strong swellings
on the pygidial axis posteriorly (more prominent on vomer) and
the acute process defining the pygidial tip distinguish vomer
and johannis from other species of T. {Trimerus). These two
species differ in that vomer has more forwardly placed
eyes, distinct eye ridges, a longer preglabellar field, an entire
cephalic anterior margin, deep apodemes on SI and distinct
S2-S3 (fused to define a shallow exsagittal furrow in johannis).

As noted by Chapman (1912), Trimerus {Trimerus) vomer is
also close to the type species, T. {T.) delphinocephalus. Feint
eye ridges and very weak LI apodemes have been observed
(Whittington, 1993, fig. 2a) on delphinocephalus, and are
comparable to those on vomer (Figs 15.3-15.4) The most con-
spicuous differences include the much wider pygidial axis,
shallower pygidial furrows, the convex rostral suture, the
angular (rather than straight) connective sutures, the low
glabella and and the less elongate pygidial outline of
delphinocephalus.

The cephalon designated as paratype by Chapman and con-
sidered by him to be a juvenile form is not conspecific with the
holotype. The specimen (NMV P12303, see Fig. 20.1) lacks the
bell shaped glabellar outline and deep lateral glabellar furrows
of Trimerus {Trimerus) vomer, further differing from it in hav-
ing distinct subocular and sutural furrows. The specimen is
assigned in this work to T. {Ramiotis) otisi. Aspects of Gill’s

Figure 15. Trimerus {Trimerus) vomer (Chapman, 1912). la, NMV P136613, cephalon, dorsal view x 1.2 (latex cast) from PL286. lb, same, ven-
tral view (doublure) x 2.45. 2, NMV P136619, cranidium, dorsal view x 1.0 (internal mould) from PL286. 3a, NMV P136622, cephalon, dorsal
view x 1.15 (internal mould) from PL286. 3b, same, oblique view x 1.35. 3c, same, lateral view x 1.35. 4a, holotype NMV P12301, cephalon and
displaced, incomplete and partly enrolled thorax, anterior view of cephalon x 0.95 (internal mould) from “Wandong”. 4b, same, dorsal view of
cephalon and thorax x 0.88. 5, NMV P138649, cranidium, dorsal view x 0.92 (internal mould) from “Kilmore- Wandong”. 6, NMV P136638,
cephalon, dorsal view x 0.85 (internal mould) from “Heathcote”. 7, NMV P16415, cephalon and incomplete thorax, dorsal view x 1.0 (internal
mould) from “Wandong”. 8, paratype NMV P12302, thoracopygon, dorsal view x 0.92 (internal mould) from “Wandong”. 9a, NMV P136625,
pygidium, dorsal view x 0.85 (internal mould) from “Wandong”. 9b, same, lateral view x 1.05. 9c, same, posterior view x 0.85. 10, NMV
P137291, pygidium, dorsal view x 1.1 (internal mould) from “Wandong”. 11, NMV P137158, pygidium, dorsal view x 1.5 (internal mould) from
“Wandong”. 12, NMV P137124, pygidium, dorsal view x 1.3 (internal mould) from “Kilmore- Wandong”. 13a, NMV P455, thoracopygon,
Odorsal view x 1.1 (internal mould) from “Wandong”. 13b, same, lateral view x 1.2. 14, NMV P136637, pygidium, dorsal view x 1.05 (internal
mould) from “Langford Park homestead, Kilmore East”. 15, NMV P136633, pygidium, dorsal view x 1.25 (internal mould) from “Wandong”. 16,
NMV PI 379 10, pygidium, dorsal view x 1.0 (internal mould) from “Wandong”.

38

Andrew C. Sandford

(1949) redescription of vomer are clearly based on this
paratype, notably the description of the axial and glabellar
furrows as shallow and faint (respectively).

Documenting an increasingly distal eye position in a suc-
cession of Victorian homalonotids, Gill suggested a migration
of the Trimerus eye through time. In addition to the problem
that that the width of the librigenae and eye position for
T. ( Trimerus ) vomer is measured from the paratype cephalon of
T. (. Ramiotis ) otisi, Gill’s model is flawed firstly, in that only
two of the species in Gill’s model can be assigned to Trimerus,
secondly, in that the relative stratigraphic positions of the
species in Gill’s model are incorrect.

Environmental notes. Although no complete exoskeletons are
known from the population of Trimerus ( Trimerus ) vomer, the
articulation ratio of the population as a whole is high
(Ar=28%). T. (T.) vomer occurs in a fine siltstone lithology at
all of the few localities from which it is known. The holotype is
a cephalon displaced from an articulated thorax (Fig. 15.4),
interpreted as a moult assemblage. As for T. ( Edgillia ) king-
lakensis, articulated thoracopygons, cephalothoraxes and partly
disarticulated thoraxes are interpreted as exuvial configurations
(taphofacies TIV). An outer shelf deep-water habitat below
maximum storm wave base is suggested for vomer.

Trimerus ( Edgillia ) subgen. nov.

Type species. Trimerus kinglakensis Gill, 1949 from the Lochkovian
Hume vale Siltstone, central Victoria.

Other species included. Trimerus ( Trimerus ) grandis Benedetto and
Martel (in Baldis et al., 1976), T. ( Edgillia ) jelli sp. nov., Homalonotus
(Trimerus) mongolicus Tchemycheva, 1937, H. vanuxemi Hall, 1859.

Other species tentatively included. Homalonotus major Whitfield,
1881.

Range. Upper Silurian-Lower Devonian.

Derivation of name. For the late E. D. Gill, for his contribution
to Victorian palaeontology.

Diagnosis. Glabella subquadrate, length about 1.0 times width,
sides straight and weakly tapered (converging at around
15-20°), anterior margin transverse, well defined. S2 and S3
indistinct, SI indistinct or weakly defined, not extending to
axial furrows. Eye placed more or less opposite glabellar
midlength. Hypostomal middle furrow with deep impressions
abaxially. 10-14 pygidial axial rings. Pygidial postaxial ridge
poorly defined. Ring furrows deep, pleural furrows shallow.
Pygidial length 0.85-1.0 times width.

Discussion. Represented by a population sample of over 300
partly articulated exoskeletons, Trimerus (Edgillia) king-
lakensis is undoubtedly the best represented species of
Trimerus from the Prfdolf-Lower Devonian interval. T. (E.)
kinglakensis differs markedly from many earlier represen-
tatives of Trimerus in its glabellar morphology, principally in
having a subquadrate outline and a raised but evenly-vaulted
surface. Species assigned here to T. (Ramiotis) differs in having
a more strongly tapered and generally more elongate glabellar
outline, with many exhibiting weak glabellar lobation and
rounded anterior glabellar margins and pygidia with raised

postaxial ridges. The glabellar outline strongly expanded across
Ll-Ll (tr.), distinct glabellar lobation, paraglabellar areas, and
the presence of a glabellar longitudinal ridge and glabellar
antero-median indentation in T. (Trimerus) distinguishes
kinglakensis from that group. The morphology exhibited by
kinglakensis is shared with several poorly known Upper
Silurian-Lower Devonian taxa and defines a species group for
which T. (Edgillia) is established.

Homalonotus vanuxemi from North America is roughly con-
temporary with Trimerus (Edgillia) kinglakensis, occurring in
Lower Devonian strata of New York State. The species was
originally described from its thorax and pygidium (Hall, 1859).
The later documentation of the cranidium (Hall and Clarke,
1888: p. 11, plate 5b, Williams and Breger, 1916: plate 22, figs
12, 21, Shimer and Shrock, 1944: plate 272, fig. 32) demon-
strates a cephalic morphology closely comparable with king-
lakensis. In particular, the straight sides, transverse anterior
margin and weakly tapered outline and proportions of the
glabella of vanuxemi are almost identical to the Victorian
species. With respect to the morphology of the preglabellar
field, the illustrations of the cranidium by Hall and Clarke and
Shimer and Shrock are not in close agreement. Hall and Clarke
noted an exceptionally long preglabellar field and a transverse
rostral suture, although their observations were based on a
single fragment. Shimer and Shrock illustrated a complete
cranidium with a somewhat shorter preglabellar field, and
although the rostral suture is not clearly depicted it appears
forwardly convex in outline. In these respects the cephalon
illustrated by Shimer and Shrock is very close to kinglakensis
and supports assignment of vanuxemi to T. (Edgillia). The
pygidia of these two species also share a relatively high degree
of segmentation and both lack a raised postaxial ridge. The rel-
ative depth of the pygidial pleural furrows of vanuxemi is diffi-
cult to ascertain from the illustrations available. However, Hall
and Clarke’s illustration of a large specimen in lateral view
(Hall and Clarke: pi. 5b fig. 2) suggests shallower pleural
furrows than the ring furrows, as in kinglakensis.

Trimerus (Trimerus) grandis from the Upper Silurian-Lower
Devonian of Argentina was described by Benedetto and Martel
in Baldis et al. (1976) from a single specimen. Assignment of
this species to T. (Edgillia) is supported by the raised, evenly
vaulted glabellar profile, the subquadrate glabellar outline, the
poorly defined glabellar lobation, and the relative shallowness
of the pygidial pleural furrows relative to the ring furrows. The
higher degree of pygidial segmentation (11-12 axial rings) is in
accord with assignment to T. (Edgillia).

A new species represented almost entirely by fragmented
tergites from the Lochkovian of Victoria can also be assigned to
Trimerus (Edgillia). The material available is closely compar-
able to T. (E.) kinglakensis and T. (E.) vanuxemi and is
described in this work as T. (E.) jelli. There are few other
homalonotids recorded from the Lower Devonian that can be
confidently assigned to T. (Edgillia). Homalonotus major was
described from a single, incomplete but very large thoracopy-
gon. Whitfield (1881) estimated the specimen to represent an
individual 15.5 inches (31 cm) and in its very large size
the species is comparable to kinglakensis, vanuxemi and T. (E.)
grandis. The depth of the axial ring and pleural furrows of

Homalonotid trilobites from the Silurian and Lower Devonian

39

major and kinglakensis are comparable, although those of
major do not appear to shallow abaxially. The specimen has 10
axial rings, although the posterior part of the pygidium is
broken off and whether there were further rings or a postaxial
ridge cannot be determined. On these few features the species
is only doubtfully assigned to Edgillia.

Gill (1949) considered Trimerus C Edgillia ) kinglakensis to
be most closely related to, and directly descended from, the
earliest Ludlow T. (T.) vomer. Gill constructed his phylogeny
erroneously considering these species to be much closer in age
than they actually are. Redescription of both vomer and
kinglakensis shows that these species are not closely related.
T. (T.) vomer is a highly derived species and kinglakensis
exhibits none of its characteristic features. With respect to the
presumably ancestral T. ( Ramiotis ), morphoclines of increasing
glabellar complexity defining T. ( Trimerus ) are contrary to
morphoclines of decreasing glabellar complexity characterising
T. ( Edgillia ) and suggest independent derivation of these
subgenera.

Trimerus {Edgillia) kinglakensis (Gill, 1949)

Figures 5A, 5D, 16, 17.1-17.7

Homalonotus sp. — Gill, 1947: 13.

Trimerus kinglakensis Gill, 1949: 67, pi. 8 figs 1-3, pi. 9 figs 3, 5-6,
text-fig. IE. — Williams, 1964: table 1. — Wenndorf, 1990: 16. — Jell,
1992: 11, text-fig. IB .— Schraut, 2000: 382.

Type material. Holotype NMV P14580 (cephalon, figured Gill, 1949:
pi. 8 figs 1, 2, pi. 9 fig. 3, text-fig. IE, Fig. 16.12 herein, counterpart
previously registered NMV P14581) from PL252, Williams locality
W3, Middendorps Quarry, Kinglake West, Victoria. Paratype NMV
P14582 (thoracopygon, figured Gill, 1949: pi. 8 fig. 3, counterpart
previously registered NMV P14583) from PL252. For locality see
Fig. 11.

Previously jigured material. NMV P14584 (thoracopygon, figured
Gill, 1949: pi. 9 fig. 5), NMV P14585 (pygidium, figured Gill, 1949:
pi. 9 fig.6, counterpart previously registered NMV P14586) from
PL252.

Registered material. 307 specimens: 2 dorsal exoskeletons, 22 articu-
lated thorax-pygidia with displaced cephala, 29 articulated thoraxes
with displaced cephala, 12 articulated thorax-pygidia with inverted
cephala, 3 articulated thoraxes with inverted cephala, 3 articulated
thoraxes with displaced cephala and pygidia, 110 articulated or partly
disarticulated thoraxes with attached pygidia, 10 articulated or partly
disarticulated thoraxes with displaced pygidia, 32 cephala, 4 cranidia,
1 librigena, 30 articulated or partly disarticulated thoraxes, 50 pygidia.
NMV P149634, P149635, NMV P305248-P305545 from PL252.
NMV P305546 from “Kinglake”, Victoria. NMV P305547 from “King
Parrot Creek”, Kinglake West. NMV P304849 from PL6640, Garratt
locality M8, Heathcote Junction. NMV P304850 from PL6641,
Williams locality G96, Clonbinane. NMV P304853, P304854? from
PL6645, Williams locality W47, Humevale. NMV P304852? from
PL6648, Humevale. NMV P304857? from PL6659, Williams locality
W8, Kinglake West. NMV P304856 from PL6660, Humevale.
Unregistered specimen from PL229, Williams locality W7, Collins
Quarry, Kinglake West. For localities see Fig. 11. NMV
P305548-P305550 from “Christmas Hills”, Victoria (probably in the
vicinity of PL261). For locality see Jell and Holloway, 1983: fig. 1.
NMV P305551, P305552 from old Scoresby Brick Pit, Wantirna
South, Victoria.

Stratigraphic distribution. Humevale Siltstone (from basal horizons
at the old Scoresby Brick Pit to the Collins Quarry Sandstone Member
at the top of the unit), upper Notoparmella plentiensis-Boucotia janae-
Boucotia australis assemblage zones, Pfidoli -Lochkovian.

Revised diagnosis. Cranidial width 1.5 times length. Glabella
trapezoid, length more or less equal to width, sides straight,
converging at about 15°, anterior margin well defined.
Proximal section of SI moderately impressed, directed diag-
onally, glabellar lobation otherwise poorly defined.
Preglabellar field 0.2 times cranidial length. Palpebral lobes
placed opposite glabellar midlength/0.4 cranidial length and
remote (5-6 1.55 times preoccipital glabellar width). Anterior
branches of facial suture angular, parallel to axial furrows for a
short distance posteriorly, converging at about 80° anteriorly.
Librigenal border furrow weakly defined. Course of rostral
suture angular, defining an obtuse angle of about 140°, dorsal
section of rostral plate boomerang-shaped. Hypostome with
middle furrow very deep, posterior border with wide, short
triangular lobes (length 0. 1 times hypostomal length) and deep,
angular medial notch. Pygidium triangular, length 0.95 times
width, with long pointed tip, sides straight, converging at about
75°. Axial furrows moderately impressed opposite first ring,
deep posteriorly. Axial width 0.45 times pygidial width. 13-14
axial rings. 7 pleural ribs, rib-ring medially offset at third rib,
pleural furrows markedly shallowing abaxially. Dorsal
exoskeleton very strongly pitted.

Description. Exoskeleton large, maximum size estimated 25 cm (from
NMV P305258), occipital/pygidial convexity (tr.) moderate. Pygidial
and librigenal doublure and hypostome finely ornamented with short
ridges.

Cephalon with rounded triangular outline with weakly convex
sides, converging forwards at about 70° opposite genal field and at
115° opposite rostral plate, length 0.66 times width. Glabellar length
about equal to width (although difficult to quantify due to the poor
definition of the axial furrows posteriorly), width about 0.5 times
cranidial width, sides straight to weakly convex, length 0.8 times cra-
nidial length, anterior margin transverse, medial indentation moder-
ately impressed to absent. Glabellar lobation very weakly defined,
generally only the proximal part of SI distinct, S2 distinct only on
smallest specimens (e.g. NMV P305272, see Fig. 16.10). S3 indistinct.
Occipital ring 0.1 times cranidial length, slightly wider medially.
Occipital furrow deep with weak forward flexure medially. LI 0.35
times glabellar length. SI strongly convex, weakly impressed to indis-
tinct adjacent to axial furrow, moderately impressed and directed
diagonally (posteromedially) abaxially. S2 a very weak depression
adjacent to axial furrow or indistinct, rarely extending adaxially, trans-
verse. Axial furrows shallow to indistinct and directed obliquely oppo-
site paraglabellar area and across occipital furrow, deep anteriorly.
Paraglabellar area weakly defined. Preglabellar field flat (tr. sect.).
Length (exsag.) of posterior border equal to occipital length adaxially,
lengthening to 1.5 times occipital length abaxially. Posterior border
furrow transverse, very wide, moderately impressed, terminating dis-
tally. Postocular fixigenal area long, length (exsag.) 0.21 times cran-
idial length. Palpebral lobe 0.14 times cranidial length, 6-6 1.64 times
glabellar width, palpebral furrow indistinct. Preocular fixigenal area of
moderate width, 0.17 times 6-5, narrowing markedly anteriorly, eye
ridges not distinct. Anterior branches of facial suture meeting connec-
tive sutures opposite 0.9 cephalic length. Librigena with wide, moder-
ately impressed border furrow anterior of eye, not defined opposite
preglabellar field, librigenal field weakly convex, steeply inclined.

Homalonotid trilobites from the Silurian and Lower Devonian

Dorsal section of connective sutures diverging at about 90°. Dorsal
surface of rostral plate length (sag.) 0.5 times cranidial length, very
weakly concave (tr. sect.). Rostral suture moderately convex. Ventral
surface of rostral plate kite-shaped, with length 0.9 times width,
posterior width 0. 1 maximum times width. Connective sutures angular,
anterior section converging posteriorly at about 30°, posterior section
converging posteriorly at about 70°. Librigenal doublure with wide,
shallow vincular furrow, indistinct anteriorly. Hypostomal suture
broadly concave.

Hypostome with length 0.75 times width, anterior wings large,
width 0.35 times hypostomal width.

Thorax with thirteen segments. Axial furrows defined by shallow to
moderately impressed, diagonally directed furrows on each segment,
each meeting posterior margin at indentation that correspond to deep
pits (axial articulating process) on internal mould. Pleural furrows
wide and deep, pleural tips rounded.

Pygidium triangular, with sides weakly concave. Pygidial axis with
sides straight and tapering at about 30°. Axis reaching 0.85 times
pygidial length. Terminal piece parabolic in outline, length 0.08 times
axial length, posterior margin moderately to weakly defined. Postaxial
ridge not defined. Ring furrows short (sag.) and deep. Pleural furrows
wide and deep adjacent to axial furrows, shallowing markedly abaxial-
ly, reaching wide and very shallow border furrow. Interpleural furrows
very weakly defined. Border weakly defined. Pygidial doublure flat
and weakly inclined posteriorly, laterally with angular profile (tr.
section), distal surface horizontal, proximal surface increasingly
inclined anteriorly. In posterior view anterior margin of pygidium
moderately convex, posterior margin without distinct medial arch.

Remarks. Gill’s (1949) original description is not detailed but
documents most of the characters listed in the revised diag-
nosis. Gill described the glabellar furrows as absent, but the
proximal portion of SI is manifest as a short, moderately
impressed diagonal furrow.

Trimerus ( Edgillia ) kinglakensis can be closely compared to
the poorly known T. (E) vanuxemi from the Helderbergian of
North America. In addition to the shared cephalic and pygidial
features listed above as defining T. {Edgillia), the species share
a forwardly convex rostral suture, a similar pygidial rib-ring
offset (third-fourth? rib). The species differ in that vanuxemi
exhibits longer glabellar proportions, shorter cephalic and
pygidial proportions, a greater number of pleural ribs, a wider
pygidial axis, and lacks a produced pygidial tip. In the depth of
the pygidial axial furrows and ring and pleural furrows,
kinglakensis shows closer resemblance to T. (E?) major , also
from the Helderbergian of North America. However, major
differs from kinglakensis in that the pleural furrows do not

41

shallow abaxially. Pygidial morphology of the Late Silurian
T. (E.) mongolicus is closely comparable to that of kinglaken-
sis. The Mongolian species exhibits similar proportions, 13
pygidial axial rings, deep ring furrows and shallow pygidial
pleural furrows and an acuminate tip. T. (E.) kinglakensis
differs in having deeper pygidial axial furrows, a shorter
preglabellar field, and in the strong convexity of the rostral
suture. Although the course of the rostral suture has been
emphasised in the diagnoses of higher taxa (e.g. medial flexure
in Burmeisteria, concavity in Digonus: see discussion above),
variability in the forward curvature of the rostral suture
amongst Trimerus is considered only of specific significance.
Apart from kinglakensis and vanuxemi, few species of Trimerus
exhibit strongly forwardly convex rostral sutures, the most
notable exceptions being the type species T. (T.) del-
phinocephalus and T. (T) flexuosus. Other features of these
latter species are considered characteristic of T. ( Trimerus )
and T. {Ramiotis) respectively, and indicate that they are not
closely related to kinglakensis.

Environmental notes. See discussion on taphonomy and bio-
facies. Trimerus {Edgillia) kinglakensis is considered to have
inhabited mid- to outer-shelf environments.

Trimerus ( Edgillia ) jelli sp. nov.

Figure 17.8-17.19

Homalonotidae gen. et sp. indet. 3 — Holloway and Neil, 1982: 146,
fig. 4M-R.

Type material. Holotype NMV P82873 (pygidium) from PL2288,
Thomas locality F25, Parish of Redcastle, Heathcote, Victoria (Fig.
17.9). Paratypes NMV P78300 (ex GSV48930, figured Holloway and
Neil, 1982: fig. 4R), NMV P304610 (cranidia), NMV P304612
(thoracic segment), NMV P78298 (pygidium, ex GSV48942, figured
Holloway and Neil, 1982: figs 4M, 4N, 4Q) from PL2319, Thomas
locality F55, Parish of Redcastle, Heathcote. Paratypes NMV P304638
(cranidium), NMV P304633-4 (librigenae), NMV P304635 (hypos-
tome), NMV P304636, P304637 (thoracic segments), NMV P304639
(pygidium) from PL6652, Heathcote. Paratype NMV P78299 (libri-
gena, figured Holloway and Neil, 1982: figs 40, 4P) from PL2288. For
localities see Fig. 8.

Registered material. 45 specimens: 6 cranidia, 3 librigenae, 1 hypos-
tome, 25 thoracic segments, 8 pygidia. NMV P82925 (ex GSV48928),
NMV P3 046 1 0-P3 0462 5 , NMV P304626 (ex GSV48933),
GSV48944, GSV48938 from PL2319. NMV P82873, NMV
P304628-P304632 from PL2288. NMV P304633-P304647 from
PL6652. Unregistered specimen from PL2328, Heathcote.

Figure 16. Trimerus {Edgillia) kinglakensis (Gill, 1949). 1, NMV P305261, cranidium, dorsal view x 0.6 (internal mould) from PL252. 2a, NMV
P305257, cephalon and hypostome, dorsal view of cephalon x 0.75 (latex cast) from PL252. 2b, same, dorsal view of hypostome x 1.6. 2c, same,
ventral view of cephalon (doublure) and hypostome x 1.4. 3, NMV P305256, cephalothorax, dorsal view of cephalon x 0.85 (latex cast) from
PL252. 4, NMV P305262, cephalon, dorsal view x 0.85 (latex cast) from PL252. 5, NMV P305265, cephalon, hypostome and displaced thora-
copygon, dorsal view of hypostome x 1.55 (latex cast) from PL252. 6a, NMV P305250, cephalon, dorsal view x 0.95 (latex cast) from PL252.
6b, same, lateral view x 1.0. 7a, NMV P305264, pygidium, posterodorsal view x 0.85 (latex cast) from PL252. 7b, same, lateral view x 1.4. 8,
NMV P305248, cephalon, ventral view (doublure) x 1.0 (latex cast) from PL252. 9, NMV P305252, cephalon, oblique view x 0.7 (internal mould)
from PL252. 10, NMV P305272, cephalon, dorsal view x 3.1 (internal mould) from PL252. 11, NMV P305260, thoracopygon, dorsal view of
pygidium x 0.7 (latex cast) from PL252. 12, holotype NMV P14580, cephalon, dorsal view x 0.75 (internal mould) from PL252. 13, NMV
P305258, thoracopygon, dorsal view x 0.6 (latex cast) from PL252. 14a, NMV P305263, pygidium, dorsal view x 1.1 (latex cast) from PL252.
14b, same, x 1.0 (internal mould). 15, NMV P305253, cephalon, ventral view (doublure) x 1.6 (latex cast) from PL252. 16, NMV P305254,
cephalon, dorsal view, enlargement of anterior margin x 2.9 (latex cast) from PL252.

42

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

43

Stratigraphic distribution. Stoddart Member, Mt Ida Formation, 200 m
to 500 m above the base of the unit, Boucotia australis Assemblage
Zone, mid-late Lochkovian.

Derivation of name. For Peter Jell (Queensland Museum), for
his contribution to Victorian palaeontology.

Diagnosis. Glabella with very weakly defined lobation, sides
straight and converging at about 15°, anterior margin well
defined, transverse, with broad medial depression. Axial fur-
rows poorly defined posteriorly. Preglabellar field long, length
0.45 times anterior width of glabella (estimated 0.25 times
cranidial length). Anterior branches of facial suture converging
at 40°. Anterior margin of cranidium (including rostral suture)
transverse. Palpebral lobe placed with midline opposite
(estimated) 0.35 cranidial length. Hypostome with large, broad-
based rounded lobes on the posterior margin. Thoracic pleurae
with bilobed tips. Pygidium triangular, length equalling width,
sides straight, converging at 60°. Axis with 10 rings, width 0.46
times pygidial width, length 0.8 (estimated) times pygidial
length. Axial furrows very shallow. 6 pleural ribs. Pleural off-
set at third rib. Ring furrows moderately impressed, pleural
furrows very shallow to indistinct, increasingly so posteriorly.

Discussion. Although most specimens assigned to this species
are fragmentary, the morphology is distinctive enough to
warrant description. The weakly convergent glabellar sides, the
transverse and well-defined anterior margin and the simple
glabellar morphology support assignment to Edgillia.

In cephalic features Trimerus { Edgillia ) jelli differs from
T. (E.) kinglakensis and T. (E.) vanuxemi in the transverse
course of the rostral suture. Pygidial axial, ring and pleural
furrows of vanuxemi are moderate to shallow in depth. In
kinglakensis , the axial furrows and ring furrows are deep, with
pleural furrows shallower, and markedly shallowing distally.
The pygidium of jelli also exhibits pleural furrows shallower
than the ring furrows, but is distinctive in that the pleural
furrows are very shallow. The weakly defined segmentation is
comparable to that of the Llandovery-lower Wenlock species of
T. ( Ramiotis ), although jelli differs from these in having a more
elongate pygidial outline and in lacking the raised postaxial
ridge typical of T. {Ramiotis). In these respects the pygidia of
jelli more closely resemble pygidia of species assigned in this
work to Burmeisteria, in particular B. clarkei and B. linares.

However, the strong segmentation shared by clarkei and linares
suggest that similarities in the pygidial outline and depth of
pygidial axial ring and pleural furrows are not of high taxo-
nomic significance. The distinctive (straight-sided, weakly
furrowed) pygidial morphology shared by these three taxa and
others such as as Dipleura garratti suggests the morphology is
homologous.

Hypostomes are known for few species of Trimerus. The
hypostome of T. {Edgillia) jelli (Fig. 17.12) closely resembles
that of T. {E.) kinglakensis (Fig. 16.2). These both differ from
the hypostome of T. (T.) delphinocephalus (Whittington, 1993:
fig. IB) and T. {Ramiotis) rickardsi (Fig. 18.6) in having larger
posterior border lobes and deeper middle furrows.

Environmental notes. Trimerus {Edgillia) jelli is considered to
have inhabited high-energy, very shallow environments.

Trimerus ( Ramiotis ) subgen. nov.

Type species. Trimerus ( Ramiotis ) rickardsi sp. nov., from the upper
Llandovery ( crenulata Biozone) Chintin Formation, central Victoria,
Australia.

Other species included. Platycoryphe dyaulax Thomas, 1977, Trimerus
( Ramiotis ) iani sp. nov., T. permutus Tomczykowa, 1978 (nom. nov.
for T. lobatus Tomczykowa, 1975 non Prouty, 1923), T. (R.) otisi sp.
nov., T. {R.) tomczykowae sp. nov., T. (R.) thomasi sp. nov., T. sp. {in
Edgecombe and Fortey, 2000), T. sp. {in Curtis and Lane, 1998), T. sp.
A (in Wolfart, 1961),

Other species tentatively included. Dipleura salteri Morris, 1988
(nom. nov. for Homalonotus {Koenigia) ludensis Salter (1865) non H.
ludensis Murchison, 1839).

Range. Silurian.

Derivation of name. For my son Otis Rami.

Diagnosis. Glabella trapezoid or weakly expanded across Ll-
L1 (tr.), low, with sides more or less straight and weakly to
moderately convergent. SI -S3 weakly impressed. Preglabellar
field of short to moderate length (~0. 15-0.25 times cephalic
length). Hypostomal middle furrow shallow. Pygidium short,
length 0.5-1.0 times width. Postaxial ridge raised. Pygidium
with moderately acute to obtusely convergent sides (>70°), tip
without process or spine. Pygidial border furrow and ridge-like
border present in late species.

Figure 17.1-17.7 Trimerus {Edgillia) kinglakensis (Gill, 1949). 1, NMV P305264, thoracopygon, dorsal view x 0.65 (latex cast) from PL252. 2,
NMV P14584, inverted cephalon and displaced thoracopygon, dorsal view of cephalon x 0.9 (internal mould) from PL252. 3, NMV P305276,
cephalon and displaced, incomplete thorax, ventral view of cephalon (doublure) x 1.6 (latex cast) from PL252. 4, NMV P305269, incomplete
thoracopygon, ventral view of pygidium (doublure) x 0.85 (latex cast) from PL252. 5, NMV P305252, cephalon, lateral view x 0.6 (internal
mould) from PL252. 6, NMV P305255, cephalon and displaced thorax, dorsal view of cephalon x 0.85 (latex cast) from PL252. 7, NMV P305258,
thoracopygon, dorsal view of pygidium x 0.95 (latex cast) from PL252.

Figure 17.8-17.19 Trimerus {Edgillia) jelli sp. nov. 8, paratype NMV P304612, thoracic segment, dorsal view x 1.55 (internal mould) from
PL2319. 9, holotype NMV P82873, pygidium, dorsal view x 1.4 (internal mould) from PL2288. 10, paratype NMV P304636, thoracic segment,
lateral view x 2.0 (internal mould) from PL6652. 11, paratype NMV P304637, thoracic segment, lateral view x 1.9 (internal mould) from PL6652.
12, paratype NMV P304635, hypostome, ventral view x 2.0 (internal mould) from PL6652. 13a, paratype NMV P304610, cranidium, dorsal view
x 1.3 (latex cast) from PL2319. 13b, same, x 1.35 (internal mould). 14a, paratype NMV P304634, librigena, dorsal view x 1.45 (latex cast) from
PL6652. 14b, same, lateral view x 1.4. 15, paratype NMV P78300, cranidium, dorsal view x 1.1 (internal mould) from PL2319. 16a, paratype
NMV P78298, pygidium, dorsal view x 1.25 (internal mould) from PL2319. 16b, same (latex cast). 16c, same, ventral view (doublure) x 1.0
(internal mould). 16d, same, lateral view x 1.0. 17, paratype NMV P304638, cranidium, dorsal view x 1.25 (internal mould) from PL6652. 18,
paratype NMV P304633, librigena, ventral view (doublure) x 1.25 (latex cast) from PL6652. 19, paratype NMV P304639, pygidium, dorsal view
x 5.5 (internal mould) from PL6652.

44

Andrew C. Sandford

Discussion. Thomas (1977) noted that the rarity of Ashgill and
Llandovery homalonotids emphasised the morphological gap
between Ordovician and post-Ordovician genera. Reed (1918)
suggested that links between Wenlock Trimerus and
Ordovician homalonotid groups might be found in Llandovery
strata. In this context Thomas interpreted his new Saudi
Arabian Llandovery species Platycoryphe dyaulax as showing
features of both Platycoryphe/Brongniartella and Trimerus.
Thomas suggested that post-Ordovician homalonotines were
derived from Platycoryphe/Brongniartella stock, rather than
from Eohomalonotus as suggested by Sdzuy (1957). In assign-
ing dyaulax to Platycoryphe , Thomas emphasised its wider and
rounded pygidial outline, contrasting with the longer and
posteriorly pointed outlines of ‘typical’ Trimerus, i.e.
T. (Trimerus). Pygidia of dyaulax also exhibit shallow ring
furrows and very shallow to effaced axial and pleural furrows,
whereas pygidia of T. ( Trimerus ) exhibit pleural and ring
furrows of moderate depth, and of equal depth.

New species from the Llandovery and lower Wenlock of
south-eastern Australia show strong resemblances to
Platycoryphe dyaulax and define a tight species group.
Similarities in cephalic morphology between dyaulax and
Trimerus noted by Thomas are emphasised by the new
Llandovery- Wenlock taxa, and all share weakly tapering,
straight- sided, trapezoid glabellar outlines. The new south-
eastern Australia taxa exhibit pygidial proportions and segmen-
tation intermediate between dyaulax and T. ( Trimerus ) and
support Thomas’s suggestion of close affinities between
dyaulax and Trimerus. These similarities, and the weak defini-
tion of thoracic trilobation, the width of the thoracic axis and
the lower degree pygidial segmentation are emphasised here
to justify assignment of dyaulax to Trimerus rather than to
Platycoryphe or Brongniartella. T. (Ramiotis) is erected
to embrace this group of species, which includes late
Llandovery T. (R.) rickardsi from Victoria and T. (R.) iani
from Tasmania, and the early Wenlock T. (R.) tomczykowae
from Victoria.

In pygidial outline and segmentation there is a morpho-
logical gradient through time from Trimerus (Ramiotis)
dyaulax (mid Llandovery) to T. (R.) rickardsi and T. (R.) iani
(late Llandovery) with moderately impressed ring and axial
furrows and shallow pleural furrows, to T. (R.) tomczykowae
(early Wenlock) with pygidial furrows of subequal and moder-
ate depth, and to T. (Trimerus) (Wenlock-early Ludlow).
Although T. (Trimerus) appears to be derived from this group,
there are a number of new or poorly known Ludlow-Pndolf
Trimerus that share the distinctive cranidial morphology of the
Llandovery-Wenlock T. (Ramiotis). In exhibiting elongate
glabellar proportions, weakly tapered, straight-sided trapezoid
glabellar outlines, low glabellar profiles and preglabellar
fields of moderate length, these species are compatible with
assignment to T. (Ramiotis) rather than to T. (Trimerus). These
species include T. (R.) otisi and T. (R.) thomasi from Victoria,
T. (R.) permutus from Poland, and T. (R.) sp. (in Wolfart, 1961)
from Bolivia. Compared with the Llandovery-Wenlock
T. (Ramiotis), these Ludlow-Pndolf species encompass a wider
range of pygidial morphologies, particularly in length:width
proportions and depth of pygidial furrows.

Trimerus (Ramiotis) is easily distinguished from T.
(Trimerus) in that it lacks most of the characteristic cephalic
and pygidial features of the latter. Of the suite of features
listed as diagnostic for T. (Trimerus), only T. (R.) permutus
exhibits strongly expressed glabellar lobation. Several species
exhibit sagittal glabellar ridges (albeit weak), several
species exhibit distinct medial indentations of the anterior
glabellar margin, and some specimens of T. (R.) otisi show a
tendency towards outlines expanded across LI -LI (tr.) and
strongly tapered glabellar outlines. However, there are no
species of T. (Ramiotis) that exhibit a more than a few of the
characters of T. (Trimerus), justifying the grouping of the latter.
However, with the exception of the deep pygidial border furrow
and raised border, the characters distinguishing T. (Ramiotis)
from T. (Trimerus) can be considered as primitive, and hence
only subgeneric status is justifiable.

Dipleura salteri Morris, 1988 from the upper Ludlow
(Ludfordian) of England is a poorly known species represented
by a single cranidium (see Salter, 1865: p. 121, pi. 12 fig. 1).
Following Salter’s (1865) suggestion, Tomczykowa (1975) and
Morris (1988) assigned the species to Dipleura, but the forward
eye position, the long preglabellar field and the quadrate course
of the preocular facial sutures preclude assignment to that
genus and are in accord with assignment to Trimerus.
Subgeneric assignment of salteri is difficult as the species
exhibits a very strongly tapered glabellar outline comparable to
that of T. (Trimerus), but lacks the other diagnostic glabellar
features of the subgenus such as the outline strongly expanded
across Ll-Ll (tr.) and the distinct lobation. However, the strong
tapering of the glabella may be partly attributable to sagittally
oriented tectonic compression evident in the apparent con-
cavity (sag.) of the preglabellar field. In all other respects the
specimen is compatible with assignment to T. (Ramiotis), to
which it is tentatively assigned.

Trimerus (Ramiotis) dyaulax is from the Aeronian (mid-
Llandovery) convolutus Biozone. A possibly earlier origin for
Trimerus is suggested by a poorly known species from the
lower Llandovery of Paraguay. Wolfart (1961) assigned the
several cranidia representing this species to Trimerus. In having
elongate glabellar proportions, weakly tapered, straight-sided
trapezoid glabellar outlines, weak glabellar lobation and a
preglabellar field of moderate length, these can be assigned to
T. (Ramiotis). The only other Llandovery T. (Ramiotis) is rep-
resented by fragmentary pygidia from the Aeronian of Wales,
documented as T. sp. by Curtis and Lane (1998). Although
closer in age to dyaulax, the Welsh species differs markedly
from it in having moderately impressed pleural, ring and axial
furrows, in this respect closely resembling T. (R.) rickardsi.

Trimerus ( Ramiotis ) rickardsi sp. nov.

Figure 18

Type material. Holotype NMV P305556 (cephalon) from PL6361,
Springfield, Victoria (Fig. 18.1). Paratypes NMV P305553, P305554,
NMV P305557, NMV P305563 (cephala), NMV P305559-P305562,
NMV P305564 (cranidia), NMV P305582 (thoracic segment), NMV
P305572-P305574 (pygidia) from PL6361. Paratype NMV P138204
(pygidium) from PL667, Springfield. Paratype NMV PI 38207
(pygidium) from PL599, Springfield. Paratypes NMV P147779

Homalonotid trilobites from the Silurian and Lower Devonian

45

(hypostome), NMV P147772 (pygidium) from PL256, Wallan,
Victoria. For localities see Fig. 11.

Registered material. 66 specimens. 5 cephala, 15 cranidia, 6 librigenae,
1 rostral plate, 3 hypostomes, 12 thoracic segments, 24 pygidia. NMV
P305553-P305593 from PL6361. NMV P305626-P305628 from
PL6390, Springfield. NMV P138213, NMV P147771, P147772, NMV
P147774-P147777, NMV P147779-P147780, NMV P1477787 from
PL256. NMV P 1 39442-P 1 39446, NMV P305595 from “Lancefield”,
Victoria. NMV PI 38205-PI 38207, NMV P138270 from PL599. NMV
P138204, NMV P305594 from PL667. NMV P138267, NMV P147778
from PL1964, GSV locality B25, Springfield. Lithological similarities
suggests that the specimens labelled as coming from “Lancefield”
almost certainly come from the Parish of Goldie, and possibly in the
vicinity of allotments B19 and B23 (see Thomas, 1960: 1:31, 680
Lancefield Geological Sheet).

Stratigraphic horizon. Chintin Formation, upper Llandovery. Rickards
and Sandford (1998) suggested equivalence to the upper crenulata
Biozone, based on the presence of Acemaspis sp. within the unit, and
on the occurrence of crenulata Biozone graptolites in the uppermost
beds of the underlying Springfield Sandstone.

Derivation of name. For R. B. Rickards (University of
Cambridge), for his contribution to Victorian palaeontology.

Diagnosis. Cephalon rounded pentagonal, width about 1.6
times length, sides converging at 60° posteriorly, at 125° anter-
iorly. Glabella trapezoid, length 1.2 times width, sides sub-
parallel opposite paraglabellar areas, converging anteriorly at
about 22°. S1-S3 moderately impressed adjacent to the axial
furrow, shallow adaxially. Preglabellar field long, 0.23 times
cephalic length. Palpebral lobes placed opposite 0.42 cranidial
length/0.52 glabellar length. Anterior branches of facial suture
straight, converging at about 45°, anterior-most section curving
gently to the diagonal, continuous in curvature with broadly
rounded rostral suture. Dorsal section of rostral plate cres-
centic, length 0.1 times cephalic length. Ventral section of
rostral plate with length 0.92 times width, connective sutures
converging posteriorly at 50°. Posterior border of hypostome
with short lobes of length 0.1 times hypostomal length.
Pygidium wide, length 0.78 times width, with sides weakly
convex, converging posteriorly at about 100°. Pygidial axis
0.42 times pygidial width, with 10 axial rings. Axial furrows
straight, tapering at about 30°, shallow anteriorly, moderately
impressed posteriorly. Ring furrows deep to moderately
impressed, pleural furrows shallow. 7-8 ribs, rib-ring medially
offset at fourth rib.

Description. Exoskeleton small, maximum length 12 cm (estimated
from NMV P138204), occipital and pygidial convexity (tr.) moderate.
Dorsal exoskeleton and doublure finely granulose.

Cranidium with length (sag.) 0.9 times cephalic length. Glabella
trapezoid, length about 0.77 times cranidial length, width about 0.43
times cranidial width, anterior margin moderately well defined,
broadly rounded, medial indentation variably expressed (indistinct to
strong, e.g. NMV P305559). Glabellar lobation well defined. Occipital
ring 0.09 times glabellar length, slightly wider medially. Occipital
furrow deeply impressed with broad forward flexure medially. LI ~0.3
times glabellar length, L2 and L3 -0.1 times glabellar length and
frontal lobe -0.25 times glabellar length. S 1 weakly convex forwards
and directed posteromedially at about 25° from the transverse. S2
transverse. S3 directed antero-medially at about 10° from the trans-
verse. Axial furrows moderately impressed opposite genae, shallow

and directed diagonally opposite occipital ring. Paraglabellar area very
weakly defined. Length (exsag.) of posterior border equal to occipital
length adaxially, lengthening (exsag.) markedly abaxially to about
twice occipital length. Posterior border furrow transverse, very wide,
moderately impressed, terminating distally. Postocular fixigenal area
with length (exsag.) 0.22 times cranidial length. Palpebral lobe
short, 0. 1 times cranidial length, placed with 6-8 about 1 .77 times pre-
occipital glabellar width/0.74 times cephalic width. Palpebral furrow
wide and shallow. Preocular fixigenal area narrow (tr.), 0.17 times 8-5,
uniform in width anteriorly. Preglabellar field flat (tr. sect.). Anterior
branches of facial suture straight from eye to a point opposite
midlength (sag.) of preglabellar field, anterior section curved.
Librigenal border furrow wide and shallow opposite genal field, not
defined opposite preglabellar field, border furrow indistinct on fixi-
genae. Lateral border narrow and convex, narrowing posteriorly, indis-
tinct opposite preglabellar field and on fixigenae. Dorsal surface of
rostral plate with length 0.13 times width, anterior margin rounded.
Dorsal section of connective sutures diverging forwards at about 30°.
Ventral surface of rostral plate flat (tr, sag. sect.), kite-shaped, sides
very weakly sinusoidal. Librigenal doublure without distinct vincular
furrow. Hypostomal suture transverse.

Hypostome with moderately impressed middle furrow.

Thoracic segments with wide (sag.), deep articulating furrows, deep
and narow (exsag.) pleural furrows. Axis very weakly defined by very
shallow, wide, diagonally directed furrow. Pleural tips weakly bilobed
with larger lobe opposite posterior band and smaller lobe opposite
anterior band.

Pygidium triangular. Pygidial axis extending to about 0.9 pygidial
length, with semicircular terminal piece, length 0.1 times axial length,
continuous posteriorly with raised postaxial ridge. Ring furrows deep
to moderately impressed, pleural furrows shallow. Furrows markedly
shallower on external casts. Pleural furrows not reaching margin.
Border furrow and border poorly defined. In posterior view posterior
margin of pygidium horizontal. In lateral view dorsal profile of axis
moderately convex, postaxial ridge steeply inclined.

Discussion. Trimerus ( Ramiotis ) rickardsi is the most com-
pletely known homalonotid from the Llandovery. The species is
of primary significance in the understanding of relationships
between poorly known Llandovery homalonotids and better-
known Wenlock and Ludlow taxa.

In pygidial morphology Trimerus ( Ramiotis ) rickardsi is
typical of other Llandovery- Wenlock species, particularly in
having short pygidial proportions and much shallower ring
furrows relative to the pleural furrows. In the latter feature
rickardsi most closely resembles the very poorly known Welsh
T. (R.) sp. (see Curtis and Lane, 1998), but can be distinguished
by its higher segmentation (7 rings, 6 ribs in T. (R.) sp., cf. 10
rings, 8 ribs in rickardsi ). T. (R.) dyaulax differs from rick-
ardsi in having even shorter proportions, a rounded pygidial
tip, a low postaxial ridge, even shallower axial, ring and
pleural furrows and lower segmentation (6 rings, 5 ribs) than
counted for rickardsi. Pygidial morphology of T. (R.) iani from
the upper Llandovery of Tasmania is poorly known. The single
pygidium known exhibits segmentation comparable (9 rings, 6
ribs) to that of rickardsi, but differs in having shorter propor-
tions and a rounded tip. The relative depth of the ring furrows
compared to the pleural furrows distinguishes rickardsi from
the Wenlock T. (R.) tomczykowae from Victoria, and from other
Ludlow species of T. {Ramiotis). T. (R.) tomczykowae further
differs in having a more rounded tip. Of the Upper Silurian

46

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

47

species, T. (R.) thomasi from Victoria differs markedly in
having elongate proportions (L:W~1.0), whilst pygidia of
T. (R.) otisi from Victoria differ markedly in the depth of the
pygidial pleural and ring furrows. Despite the pygidial differ-
ences, in the more elongate glabellar outline (LAV- 1.2) the
longer preglabellar field (0.25 cranidial length), and the expres-
sion of glabellar lobation, rickardsi shows closest resemblance
to otisi. T. (R.) rickardsi differs from most other T. ( Ramiotis )
in having a forwardly convex rostral suture, comparable to that
of the Llandovery Bolivian T. (R.) sp.

In having a relatively longer preglabellar field, lateral
glabellar furrows of moderate length, a weak sagittal glabellar
ridge and, in some specimens, a distinct medial indentation of
the anterior glabellar margin, and higher pygidial segmentation
Trimerus ( Ramiotis ) rickardsi shows closer affinities to
T. ( Trimerus ) than other Llandovery T. {Ramiotis). However, in
the absence of so many of the other derived features distin-
guishing T. (Trimerus), it would be over stated to regard
rickardsi as a transitional species between the subgenera.

Environmental notes. Articulated specimens are only known
from the type locality, and represented only by cephala. The
proportion of articulated and broken specimens is 13% respec-
tively, indicative of a taphofacies TII. Further east at PL256,
Wallan, breakage of T. (R.) rickardsi and other trilobites is
extremely high and indicates significant reworking. Associated
tempestite lithologies comprising thick coquinal bioclastic lags
and abundant mud rip-up clasts indicate deposition between
normal wave base and storm wave base. The trilobite fauna
may have been transport, possibly in a tempestite-generated
mass-flow, although the profound compositional differences
between the Springfield, Wallan and Lancefield faunas do not
support this and suggest distinct, depth-related assemblages.
Trimerus (Ramiotis) rickardsi is considered to inhabit inner
shelf environments.

Trimerus ( Ramiotis ) iani sp. nov.

Figures 19.1-19.4, 19.6

Trimerus sp. — Holloway and Sandford, 1993: 93, figs 4C-D, 4F-G,
4I-J, 4N-P, non fig. 4L.

Type material. Holotype NMV PI 37221 (cephalon lacking rostral
plate, figured Holloway and Sandford, 1993: 4F-G, 4J, Fig. 19.1 here-
in) from PL359, Tiger Range, northwest of Maydena, Tasmania.
Paratypes NMV PI 37222 (cranidium, figured Holloway and

Sandford: 41), NMV PI 37227 (pygidium, figured Holloway and
Sandford: 4N-P), NMV PI 37224 (cephalon, figured Holloway and
Sandford: 4C), NMV P137223 (cephalon and two displaced thoracic
segments) from PL359. For locality see Holloway and Sandford: fig. 1

Previously figured material. NMV PI 37225 (librigena, figured
Holloway and Sandford, 1993: 4D) from PL359.

Other material. NMV P137226 (cephalon) from PL359.

Stratigraphic distribution. As for Brongniartella sp.

Derivation of name. For my brother Ian.

Diagnosis. Cephalon rounded triangular, length -0.7 times
width, sides (opposite midlength) converging at -60°. Glabella
trapezoid in outline, length 1.2 times width, sides very weakly
concave and tapering at 20° anteriorly, anterior glabellar
margin transverse, without distinct medial indentation. SI -S3
and sagittal glabellar ridge very weakly defined. Preglabellar
field of moderate length (0.2 times cranidial length), rostral
suture transverse, dorsal section of rostral plate short, 0.05
times cephalic length. Eye placed opposite -0.5 cranidial
length (-0.6 glabellar length). Anterior branches of facial
sutures converging at 60°, curving abruptly adjacent to con-
nective sutures. Ventral surface of rostral plate elongate
pentangular in outline, with connective sutures converging pos-
teriorly at 45°. Pygidium short. Axis 0.45 times pygidial width,
raised posteriorly, 10 rings, ring furrows moderately impressed.
6 ribs, pleural furrows shallow. Axial furrows moderately
impressed.

Discussion. Trimerus (Ramiotis) iani is abundant at the type
locality. Holloway and Sandford (1993) were uncertain
whether the two dissimilar homalonotid pygidia from PL359
represented different species, or whether the differences were
attributable to size differences or deformation. In reviewing this
conclusion, I cannot attribute the contrast between the narrow,
concave- sided and strongly raised axis of the smaller specimen
(see Holloway and Sandford, 1993: fig. 4L) and the wide,
convex-sided and low axis of the larger specimen entirely to
deformation (see Fig. 19.6). The more elongate (length=width)
and parabolic outline and the indication of a distinct border
suggest that the smaller pygidium represents a separate species,
referable to Brongniartella (see above).

The diagnosis includes a number of features not listed in the
brief description of the species by Holloway and Sandford
(1993). Of the two cephala not figured by Holloway and

Figure 18. Trimerus (Ramiotis) rickardsi sp. nov. la, holotype NMV P305556, cephalon, oblique view x 1.7 (internal mould) from PL6361. lb,
same, dorsal view, lc, same (latex cast). 2, paratype NMV P305560, cranidium, dorsal view x 2.4 (latex cast) from PL6361. 3, paratype NMV
P305561, cranidium, dorsal view x 1.4 (internal mould) from PL6361. 4, paratype NMV P305557, cephalon, dorsal view x 2.1 (internal mould)
from PL6361. 5, paratype NMV P305564, cranidium, dorsal view x 2.1 (latex cast) from PL6361. 6, paratype NMV P147779, hypostome,
ventral view x 2.7 (latex cast) from PL256. 7, paratype NMV P305562, cranidium, dorsal view x 1.6 (internal mould) from PL6361. 8a, paratype
NMV P305559, cranidium, dorsal view x 1.5 (internal mould) from PL6361. 8b, same, x 1.6 (latex cast). 9, paratype NMV P305554, cephalon,
ventral view (doublure) x 1.75 (internal mould) from PL6361. 10a, paratype NMV P305582, thoracic segment, lateral view x 2.5 (internal mould)
fromPL6361. 10b, same, dorsal view x 2.2. 11, paratype NMV P305 5 63, cephalon, dorsal view x 2.4 (internal mould) fromPL6361. 12a, paratype
NMV P305553, cephalon, dorsal view x 1.5 (internal mould) from PL6361. 12b, same, lateral view x 2.0. 13a, paratype NMV P305573,
pygidium, dorsal view x 1.9 (latex cast) from PL6361. 13b, same, x 2.2 (internal mould). 14, paratype NMV P147772, pygidium, dorsal view
x 2.0 (latex cast) from PL256. 15, paratype NMV P138204, pygidium, dorsal view x 1.4 (internal mould) from PL667. 16, paratype NMV
P305574, pygidium, lateral view x 2.5 (latex cast) from PL6361. 17a, paratype NMV PI 38207, pygidium, dorsal view x 1.75 (latex cast) from
PL599. 17b, same, x 1.5 (internal mould). 17c, same, posterior view x 1.75. 17d, same, lateral view (latex cast). 18a, paratype NMV P305572,
pygidium, dorsal view x 1.6 (latex cast) from PL6361. 18b, same (internal mould).

48

Andrew C. Sandford

Homalonotid trilobites from the Silurian and Lower Devonian

Sandford, one specimen shows the anterior margin of the
cephalon, with the impression of the rostral suture evident on
the surface of the doublure (Fig. 19.4). The other speci-
men shows the posterior portion of the ventral surface of the
rostral plate. The pygidial pleural furrows are shallow, although
the greater depth of the first furrow appears to be partly
exaggerated by longitudinal shearing.

Holloway and Sandford (1993) distinguished Trimerus
( Ramiotis ) iani from previously documented homalonotids
from the Ludlow-Pragian strata of south-eastern Australia. Of
the species discussed by Holloway and Sandford, only speci-
mens described by Talent (1964) as “ Dipleura sp.” can be
referred to T. {Ramiotis).

In cephalic features Trimerus ( Ramiotis ) iani is similar to
T. (R.) otisi from the Ludlow of Victoria. These species share a
glabella with elongate proportions (L:W~1 .2) and moderately
tapering (-25°) and weakly concave sides, a preglabellar field
of similar length (0.2 cranidial length), similar cephalic propor-
tions (L:W ~0.7), a transverse rostral suture, very short
pygidial proportions and comparable pygidial segmentation.
T. (R.) otisi differs in having well defined glabellar lobation and
a distinctive tricuspid anterior cephalic margin. In cephalic
features T. (R.) permutus from the Ludlow of Poland is also
closely comparable, although it differs in having strongly
expressed glabellar lobation. In pygidial features iani demon-
strates its closer affinities to other Lower Silurian T. (Ramiotis),
particularly in the weak expression of the pleural furrows, the
deeper ring furrows, and the rounded tip. In pygidial morph-
ology iani is closest to T. (R.) dyaulax, that differs in having
weaker segmentation. T. (R.) iani is closest in age to the type
species T. (R.) rickardsi, but differs in having a shorter
preglabellar field, weaker glabellar lobation, a transverse
rostral suture, and a rounded pygidial tip.

Trimerus ( Ramiotis ) otisi sp. nov.

Figure 20

Homalonotus vomer . — Chapman, 1912: 298, pi. 63 fig. 1, non pi. 62
figs 2, 3, pi. 63 fig. 2.

Trimerus vomer . — Gill, 1949: 65, text-fig. IB, non text-fig. 1C.

Trimerus cf. lilydalensis. — Williams, 1964: 285, table 1.

Trimerus sp. — Garratt, 1968: 164, chart 1.

Trimerus cf. vomer . — Garratt, 1968: 164, chart 1.

Type material. Holotype NMV P304741 (cephalon and displaced tho-
racopygon) from PL1898, Eden Park, Victoria (Fig. 20.5). Paratypes

49

NMV P304727 (cephalon and displaced thoracopygon), NMV
P304722-P304724 (cephala), NMV P304726 (cranidium), NMV
P304718-P304720 (pygidia) from PL6633, Eden Park. Paratypes
NMV P304739, NMV P304797 (incomplete cephalothoraxes), NMV
P304738 (thoracopygon), NMV P304742 (pygidium) from PL1898.
Paratypes NMV P304730, NMV P304733, P304734 (cephala), NMV
P304729 (pygidium) from PL6632, Eden Park. Paratype NMV
P304737 (pygidium) from PL300, Clonbinane, Victoria. For localities
see Fig. 11.

Registered material. 141 specimens: 4 dorsal exoskeletons, 3 dorsal
exoskeletons with displaced cephala, 3 articulated cephalothoraxes, 2
thoraxes with displaced cephala, 15 cephala, 22 cranidia, 3 librigenae,
1 hypostome, 8 thoracic segments, 4 articulated thoraxes, 10 articulat-
ed thoracopygons, 66 pygidia. Eden Park: NMV P304766-P304770
from PL6627, Jutson locality VIII. NMV P304743, NMV P304775-
P304778 probably from PL6627. NMV P304771-P304773 from
PL6628. NMV P304832-P304836 from PL6629, Williams locality
F130. NMV P304745, NMV P304837-P304840 from PL6630. NMV
P304738-P304742, NMV P304779-P304799 from PL1898. NMV
P304832-P304838 from PL6631. NMV P304728-P304736, NMV
P304807-P304822 from PL6632. NMV P304718-P304727, NMV
P304747-P304765 from PL6633. NMV P304800-P304806 from
PL6635. NMV P304744 from “Eden Park”. Unregistered specimens
from PL6634 and PL6616, Williams locality XI 2. Upper
Plenty-Clonbinane area, Victoria: NMV P304774 from PL6636,
Jutson locality 111= Williams locality FI 2, Upper Plenty. NMV
P304746, NMV P304830, P304831 fromPL6638, Kenley locality 32g,
Upper Plenty. NMV P304844-P304846 from PL6639, Upper Plenty.
NMV P304841-P304843 from PL6642, Williams locality G23,
Wandong. NMV P304737, NMV P304823-P304826 from PL300.
NMV P304827-P304829 from PL1782, Clonbinane. In addition,
homalonotids recorded by Garratt (1968) from PL6618, Jutson
locality IX=Williams locality F90, Eden Park and by Williams (1964)
from Williams locality F41, Clonbinane undoubtedly refer to Trimerus
( Ramiotis ) otisi, although specimens from these localities are not rep-
resented in the MOV collections. Humevale: NMV P304851 from
PL6646, Williams locality W17. Unregistered specimen from PL6648.
For localities see Fig. 11.

Stratigraphic distribution. Eden Park Formation, from 350 m above
the base to the top of the unit, Notoparmella plentiensis Assemblage
Zone, late Ludlow.

Diagnosis. Cephalon with length 0.7 times width, anterior
margin tricuspid. Glabella trapezoid, length about 1.17 times
width, sides converging at about 25°, anterior margin strongly
defined, transverse. Glabellar lobation moderately well
defined. Palpebral lobe placed opposite 0.6 glabellar length
(0.5 cranidial length). Moderately impressed sutural and

Figure 19.1-19.4, 19.6. Trimerus ( Ramiotis ) iani sp. nov. la, holotype NMV P137221, cephalon, dorsal view (internal mould) from PL359.
lb, same, oblique view, lc, same, lateral view. Id, same, dorsal view (latex cast). 2, paratype NMV P137224, cephalon, dorsal view (internal
mould) from PL359. 3, paratype NMV P137222, cranidium, dorsal view (internal mould) from PL359. 4, paratype NMV P137223, cephalon,
dorsal view (internal mould) from PL359. 6a, paratype NMV P137227, pygidium (internal mould) lateral view, from PL359. 6b, same, posterior
view. 6c, same, dorsal view.

Figure 19.5, 19.8, 19.10, 19.12. Trimerus ( Ramiotis ) tomczykowae sp. nov. 5, paratype NMV P305191, cranidium, dorsal view x 1.1 (internal
mould) from PL2263. 8, holotype NMV P138203, pygidium (internal mould) x 1.5, from the “ Illaenus band”, Costerfield South. 8a, posterior
view. 8b, dorsal view. 8c, lateral view. 10, NMV P138291, cephalon (fragment), dorsal view (latex cast) from PL1460. 11, paratype NMV
P138293, rostral plate, dorsal view x 6.0 (latex cast) from PL1460.

Figure 19.7, 19.9, 19.11. Trimerus ( Trimerus ) harrisoni (McCoy, 1876). 7, holotype NMV P7503, complete exoskeleton, dorsal view x 1.8 (inter-
nal mould) from PL1620. 9, NMV P136645, complete exoskeleton, dorsal view of cephalon with impression of hypostome x 2.1 (internal mould)
from PL1620. 11, NMV P2500, complete exoskeleton, lateral view x 2.6 (internal mould) from PL1620.

Homalonotid trilobites from the Silurian and Lower Devonian

sub-ocular furrows, weak eye ridges. Preglabellar field 0.2
times cranidial length. Anterior branch of facial suture straight
poster-iorly, converging at about 55°, then anteriorly curving
strongly to the transverse, rostral suture transverse. Dorsal sur-
face of rostral plate semicircular, without connective sutures,
equal in length to preglabellar field. Ventral surface of rostral
plate with length equalling width, connective sutures moder-
ately convex and converging posteriorly at about 90°. Pygidium
triangular, short, length 0.6 times width, with sides weakly con-
vex and converging posteriorly at about 110° to an obtusely
pointed tip. Pygidial axis narrow, width (measured across sec-
ond ring) 0.3 times pygidial width, 10 axial rings, ring furrows
deep. 7-8 pleural ribs, pleural furrows as deep as ring furrows
and uniform in depth to lateral border furrow, rib-ring medial-
ly offset at fifth rib. Axial furrows moderately impressed poste-
riorly, poorly defined anteriorly, postaxial ridge posteriorly
raised. Lateral border furrow well defined, border a raised
ridge.

Discussion. The distinctive tricuspid cephalic margin immed-
iately distinguishes Trimerus ( Romiotis ) otisi from all other
members of the genus. The pygidium of otisi is also distin-
guishes the species from many congeners, with deep pleural
and ring furrows and the anteriorly indistinct axial furrow
shared only with the Bolivian T. (R.) sp. A. The Bolivian
species also displays a well defined border furrow and border
comparable to that of otisi and T. (R.) thomasi, but the species
differs in having longer pygidial proportions (L:W~0.9) and a
wider pygidial axis (width 0.5 pygidial width). The very short
pygidial proportions of otisi are closest to those of T. (R.) iani,
that also shares comparable cephalic features including moder-
ate length of the preglabellar field, longer glabellar proportions,
a glabellar outline weakly expanded across LI -LI (tr.), and a
forward eye position (opposite 0.5 cranidial length). In addition
to the tricuspid margin, otisi differs from iani in having distinct
subocular furrows and eye ridges.

The tricuspid cephalic margin of Trimerus ( Ramiotis ) otisi is
comparable to that of Digonus, as is the quadrate course of the
preocular facial sutures and the very weak expression of the
pygidial axial furrows anteriorly, with up to the third rib fused
with the axial rings. The species also resembles Digonus in the
very deep and equally deep pleural and ring furrows. The mod-

51

erately well defined glabellar lobation and glabellar outline
weakly expanded across LI -LI (tr.) are comparable to early
Digonus morphologies best represented by D. zeehanensis, and
in these respects otisi is the best candidate as an intermediate
species between Trimerus and Digonus. Significant features
precluding the assignment of otisi to Digonus include the lack
of a ventral process on the rostral plate, the very narrow pygidi-
al axis, and the strongly raised postaxial ridge. T. (R.) otisi and
Digonus further differ in the expression of the dorsal sections
of the connective sutures (short in Digonus but absent in otisi),
and in the size of the medial cephalic process (small in Digonus
but very large in otisi). In the large size of the medial cephalic
cusp, otisi is most closely comparable to T. (T.) johannis.
However, marked differences in cephalic morphology between
tricuspid T. {Trimerus) (represented by johannis), T. ( Ramiotis )
(represented by otisi) and Homalonotus suggest that the tri-
cuspid cephalic margin was independently derived in these
groups.

The paratype cephalon of Homalonotus vomer (NMV
P12303, Fig. 20.1 and figured Chapman, 1912, pi. 63 fig. 1,
Gill, 1949, text-fig. IB) belongs to Trimerus {Ramiotis) otisi,
and is designated a paratype of the new species. Chapman
(1912) considered the specimen to be a juvenile form of vomer,
but did not otherwise compare it with the holotype cephalon.
Although Chapman’s description of vomer seems to be based
entirely on the holotype, Gill (1949) included features of the
paratype in his redescription of the species. Chapman and Gill
recorded the localities of the paratype and the holotype of
vomer only as “Wandong”. The holotype was almost certainly
collected from PL286 (Williams locality F22, Wandong),
where the species occurs in relative abundance and in an
identical lithology to that of the holotype. As noted by Gill, the
paratype occurs in a yellow-brown, fine grained sandstone.
T. {R.) otisi has been collected from similar lithologies in the
Merriang Syncline to the east of Wandong, and it is presumed
the specimen was collected in that area, and probably in the
vicinity of PL300, Comet Creek Mine, Clonbinane.

It is remarkable that although Trimerus {Ramiotis) otisi is
very common in the Eden Park Form a tion in the Merriang
Syncline between Merriang and Clonbinane, trilobites (pre-
dominantly homalonotid) are exceedingly rare in the equivalent
horizons of the nearby Kinglake Basin sequence.

Figure 20. Trimerus {Ramiotis) otisi sp. nov. la, paratype NMV P12303 (and paratype of Homalonotus vomer Chapman, 1912), cephalon, dorsal
view x 1.9 (latex cast) from Wandong (exact locality unknown), lb, same, x 1.7 (internal mould). 2, paratype NMV P304726, cranidium, dorsal
view x 2.7 (latex cast) from PL6633. 3, paratype NMV P304739, incomplete cephalothorax, dorsal view x 3.2 (latex cast) from PL1898. 4,
paratype NMV P304797, incomplete cephalothorax, dorsal view of cephalon x 2.7 (internal mould) from PL 1898. 5a, holotype NMV P304741,
cephalon and displaced thoracopygon, dorsal view of cephalon x 1.15 (internal mould) from PL 1898. 5b, same, enlargement of anterior margin
x 2.3. 5c, same, anterior view of cephalon x 1.15. 6, paratype NMV P304727, cephalon and displaced thoracopygon, dorsal view of cephalon x
2.75 (internal mould) from PL6633. 7, paratype NMV P304723, cephalon, enlargement of anterior margin x 1.6 (internal mould) from PL6633.
8, paratype NMV P304722, cephalon, enlargement of anterior margin x 2.3 (latex cast) from PL6633. 9a, paratype NMV P304730, cephalon,
anterior view x 2.1 (latex cast) from PL6632. 9b, same, oblique view. 9c, same, dorsal view. 10, paratype NMV P304738, thoracopygon, dorsal
view x 3.0 (latex cast) from PL1 898. 11, paratype NMV P304734, cephalon, dorsal view x 4.3 (internal mould) from PL6632. 12, paratype NMV
P304733, cephalon, ventral view (doublure) x 2.0 (latex cast) from PL6632. 13, paratype NMV P304724, cephalon, ventral view (doublure) x 3.4
(latex cast) from PL6633. 14a, paratype NMV P304720, pygidium, lateral view x 1.9 (latex cast) from PL6633. 14b, same, dorsal view x 1.8. 15a,
paratype NMV P304719, pygidium, dorsal view x 1.15 (latex cast) from PL6633. 15b, same, lateral view. 16a, paratype NMV P304729,
pygidium, dorsal view x 1.7 (latex cast) from PL6632. 16b, same, posterior view x 1.6. 17, paratype NMV P304742, pygidium, dorsal view x 2.4
(internal mould) from PL 189 8. 18, paratype NMV P304737, pygidium, ventral view (doublure) x 1.45 (latex cast) from PL300. 19, paratype NMV
P304718, pygidium, dorsal view x 1.4 (internal mould) from PL6633.

Homalonotid trilobites from the Silurian and Lower Devonian

Environmental notes. See taphonomy and biofacies. Trimerus
( Ramiotis ) otisi is considered to have inhabited mid shelf
environments.

Trimerus ( Ramiotis ) thomasi sp. nov.

Figure 21

Trimerus ( Dipleura ?) sp.. — Talent, 1964: 49 (pars), fig. 6 non pi. 26
figs 1-2 ( =Digonus wenndorfi sp. nov.)

Type material. Holotype NMV P305067 (pygidium) from PL6653,
Heathcote, Victoria (Fig. 21.15). Paratypes NMV P305046-P305047
(cephala), NMV P305048, NMV P305053-P305056, NMV P305058,
P305059, (cranidia), NMV P305072-P305073 (librigena), NMV
P305061, NMV P3 04063, NMV P305068-P305070, (pygidia) from
PL2264, Thomas locality F45, Parish of Heathcote, Heathcote.
Paratype NMV P63385 (cranidium), NMV P305043 (pygidium) from
PL2265, Thomas locality F46, Parish of Heathcote, Heathcote. For
localities see Fig. 8.

Previously figured material. NMV P63385 (ex GSV38132, cranidium,
figured Talent, 1964: text-fig. 6) from PL2265.

Registered material. 94 specimens. 3 cephala, 40 cranidia, 5 librigenae,
1 thoracic segment, 45 pygidia. NMV P305042-P305045, NMV
P305 127-P305 130 from PL2265. NMV P305046-P305053, NMV
P305055-P305066, NMV P305068-P305123, NMV P305126 from
PL2264. NMV P305124-P305125, NMV P305054, NMV P305067
from PL6653. NMV P305131 from PL6654, Heathcote. NMV
P305132 from PL6655, Heathcote. NMV P305133 from PL6656,
Heathcote. Unregistered specimens from PL2234, Thomas locality
F21, Parish of Heathcote, Heathcote, PL6727, Thomas locality F28,
Parish of Redcastle, Heathcote. For localities see Fig. 8.

Stratigraphic distribution. Mclvor Formation, -500 m above the base
of the unit, lower Notoparmella plentiensis Assemblage Zone, mid
Ludlow.

Derivation of name. For Alan T. Thomas (University of
Birmingham), for his contribution to the study of homalonotids.

Diagnosis. Cephalon with length about 0.7 times width.
Glabella with length equalling width, trapezoid in outline, sides
more or less straight, tapering weakly forwards at about 25°.
Glabellar lobation distinct, SI -S3 very shallow, LI, L2, L3 and
frontal lobe subequal in length (exsag.). Anterior margin of
glabella well defined, transverse or with broad medial inden-
tation. Preglabellar field long, 0.25 times cranidial length,
slightly concave (tr. sect.). Palpebral lobe placed with midline
opposite 0.45 cranidial length (0.6 glabellar length) and with

53

8-6 1.6 times preoccipital glabellar width. Anterior margin of
cranidium transverse to very broadly convex. Pygidium with
length equal to width, sides converging at about 70°, angular
tip. Pygidial axis wide, 0.43 times pygidial width, continuous
with wide, raised postaxial area. 9 distinct axial rings, 7 distinct
pleural ribs, axial furrows shallow, pleural furrows moderately
impressed, rib-ring offset at fifth-sixth rib.

Remarks. Although specimens are abundant, the quality of the
material of Trimerus ( Ramiotis ) thomasi and its similarity to
T. (R.) otisi does not warrant a full description. The trapezoid,
straight-sided and moderately tapered glabellar outline indicate
assignment to Trimerus {Ramiotis). The moderate length of the
preglabellar field and the weak glabellar lobation are in accord
with this assignment. The cranidium figured by Talent (1964:
fig. 6) as T. (Dipleural) sp. is significantly larger than cranidia
from the type locality of T. (R.) thomasi which lies about 500m
south-east of PL2265 and more or less on strike. The larger
specimen differs conspicuously in that the anterior branches of
the facial sutures are more strongly convergent (-70°) and the
rostral suture correspondingly shorter (tr.), the preglabellar
field is slightly shorter (0.22 cranidial length), and the medial
flexure of the occipital furrow is strongly expressed (see Fig.
21.12). Whether these differences are attributable to the size or
to variability within the species cannot be resolved without
further specimens of large individuals. Within the range of
intraspecific variability, there are specimens of thomasi
exhibiting very weak lobation, and short and more strongly
tapered glabellar outlines (e.g. Figs 21.4, 21.5). These
morphs are closely comparable to the contemporary
T. (R.) salteri from England. Original illustrations of the holo-
type [Salter, 1865: pi. 12 fig. 1, as Homalonotus ( Koenegia )
ludensis ] indicates that the English species differs from thomasi
in having a wider (tr.) preocular fixigenal field and deeper axial
furrows.

Trimerus {Ramiotis) permutus from the upper Ludlow of
Poland is close in age to T. {R.) thomasi. In cephalic morph-
ology permutus differs markedly from thomasi in exhibiting
strong glabellar lobation, an elongate glabellar outline, more
strongly convergent facial sutures, and a short preglabellar
field. The species are more closely comparable on pygidial
features. Although pygidia of permutus are poorly known, they
share with thomasi the elongate pygidial proportions and mod-
erately and equally impressed axial, pleural and ring furrows.

Figure 21. Trimerus {Ramiotis) thomasi sp. nov. 1, paratype NMV P305046, cephalon, dorsal view x 2.5 (internal mould) from PL2264. 2,
paratype NMV P305048, cranidium, dorsal view x 2.5 (latex cast) from PL2264. 3, paratype NMV P305055, cranidium, dorsal view x 2.6 (inter-
nal mould) from PL2264. 4, paratype NMV P305059, cranidium, dorsal view x 2.4 (latex cast) from PL2264. 5, paratype NMV P305053,
cranidium, dorsal view x 2.7 (internal mould) from PL2264. 6, paratype NMV P305056, cranidium, dorsal view x 2.9 (latex cast) from PL2264.
7, paratype NMV P305054, cranidium, dorsal view x 2.6 (latex cast) from PL6653. 8, paratype NMV P305058, cranidium, dorsal view x 2.6 (latex
cast) from PL2264. 9a, paratype NMV P305047, cephalon, anterior view x 2.3 (latex cast) from PL2264. 9b, same, oblique view x 1.8. 9c, same,
dorsal view x 2.4. 10a, paratype NMV P305072, librigena, lateral view x 2.0 (internal mould) from PL2264. 10b, same, dorsal view (latex cast).
11, paratype NMV P305073, librigena, ventral view (doublure) x 1.7 (latex cast) from PL2264. 12, NMV P63385, cranidium, dorsal view x 1.95
(internal mould) from PL2265. 13a, paratype NMV P305068, pygidium, lateral view x 1.9 (internal mould) from PL2264. 13b, same, dorsal view.
14, paratype NMV P304063, pygidium, dorsal view x 3.0 (internal mould) from PL2264. 15a, holotype NMV P305067, pygidium, dorsal view
x 3.0 (internal mould) from PL6653. 15b, same, posterior view. 15c, same, oblique view. 16, paratype NMV P305070, pygidium, ventral view
x 4.0 (internal mould) from PL2264. 17, paratype NMV P305061, pygidium, dorsal view x 2.5 (latex cast) from PL2264. 18a, paratype NMV
P305043, pygidium, lateral view x 2.4 (latex cast) from PL2265. 18b, same, dorsal view x 2.5. 19, paratype NMV P305069, pygidium, lateral
view x 3.2 (internal mould) from PL2264.

54

Andrew C. Sandford

The pygidia differ in that thomasi exhibits a markedly raised
postaxial ridge, whilst that of permutus is low.

Trimerus ( Ramiotis ) otisi from southern central Victoria is
another contemporary of T. (R.) thomasi. Despite their geo-
graphic and temporal proximity, otisi and thomasi can be
easily distinguished. The pygidia of thomasi are much more
elongate, have a wider axis, and exhibit shallower pleural and
ring furrows and deeper axial furrows. The cranidia of thomasi
generally exhibit a more straight-sided and shorter glabellar
outline, more weakly defined glabellar lobation, and a longer
preglabellar field. Despite these differences, otisi and thomasi
are considered to be closely related. Together with the poorly
known T. ( R .) sp. A from Bolivia, the species share a distinct
pygidial morphology including pleural furrows that continue to
a deep border furrow, and a raised ridge-like border. This
pygidial morphology distinguishes this species group from
Llandovery-Wenlock T. {Ramiotis). In other respects T. (R.) sp.
A is morphologically intermediate between otisi and thomasi,
exhibiting longer pygidial proportions of the latter and deeper
pygidial pleural and ring furrows of the former.

Of the Llandovery-Wenlock species of Trimerus (Ramiotis),
T. (R.) thomasi shows greatest resemblance to T. (R.) tom-
czykowae from the Wenlock of Victoria (described below), that
also exhibits very weak lobation, a transverse rostral suture,
shorter glabellar proportions and a long preglabellar field. The
species also share moderate and subequal depth of the pygidial
pleural and ring furrows, distinguishing them from other
Llandovery-Wenlock T. (Ramiotis). T. (R.) tomcykowae differs
in having a short, rounded pygidial outline, slightly longer
glabellar proportion, and a deep medial indentation of the
glabellar anterior margin.

Environmental notes. Trimerus (Ramiotis) thomasi is the dom-
inant element of monospecific or low diversity assemblages.
Three cephala from PL2264 are the only known articulated
specimens, isolated tergites representing 97% of the entire
population, typical of taphofacies Til. The species occurs in
medium-grained sandstones, associated with a shelly fauna
dominated by gastropods and brachiopods. T. (R.) thomasi is
considered to have inhabited inner shelf environments.

Trimerus ( Ramiotis ) tomczykowae sp. nov.

Figures 19.5, 19.8, 19.10, 19.12

Type material. Holotype NMV PI 38203 (pygidium) from the “ Illaenus
band”, Costerfield, Victoria (Fig. 19.8). Paratype NMV P305191
(cranidium) from PL2263, Thomas locality F44, Parish of Dargile,
Costerfield. Paratypes NMV P138292, P138293 (rostral plates) from
PL1460, Thomas locality F43A, Parish of Dargile, Costerfield. For
localities see Fig. 10.

Registered material. 8 specimens: 1 cephalon, 3 cranidia, 2 rostral
plates, 2 pygidia. NMV P138291-P138294, NMV P138296, NMV
P139358 from PL1460. NMV P305191 from PL2263. NMV P138203
from the “ Illaenus band”.

Stratigraphic distribution. Illaenus band, Wapentake Formation.
Rickards and Sandford (1998) interpreted Ananaspis typhlagogus to
indicate a Wenlock age for these beds.

Derivation of name. For Ewa Tomczykowa (Instytut

Geologiczny, Poland) for her contribution to the study of
homalonotids.

Diagnosis. Glabella trapezoid, elongate, length ~1.1 times
width, sides parallel opposite paraglabellar area, straight and
converging at about 20° anteriorly, with extremely weak
lobation, anterior margin strongly indented. Paraglabellar area
distinct. Palpebral lobe placed at about 0.55 glabellar length.
Rostral suture more or less transverse. Dorsal surface of rostral
plate long, one third length of ventral surface, anterior margin
of rostral plate with sides converging at 115°, rounded medi-
ally. Connective sutures straight, diverging forwards at 55°.
Ventral surface of rostral plate flat, length equalling width.
Pygidial axial furrows moderately impressed. Axis about 0.4
times pygidial width, sides straight and tapering at 25°, poster-
ior third of axis moderately convex and raised, terminal piece
continuous with and not distinguishable from wide, raised,
subparallel- sided postaxial ridge. 10 axial rings, ring furrows
moderately impressed, 7 pleural ribs, pleural furrows moder-
ately impressed and equal in depth to ring furrows, shallowing
distally. Pleural offset at fourth rib.

Discussion. Trimerus (Ramiotis) tomczykowae is a very rare
element of the Illaenus band fauna. Despite the very few and
fragmentary specimens available, a fairly complete reconstruc-
tion of the cephalon can be made, and together with the single,
well-preserved pygidium clearly represents a new species of
homalonotid and a full description of the species is possible
with the material at hand. Significant cephalic characters
include the elongate, trapezoid, straight- sided, moderately
tapering glabella, the weakly expressed glabellar lobation, the
moderate length of the preglabellar field (0.25 cranidial length)
and the short pygidial proportions (LAV-0.9) indicate assign-
ment to T. (Ramiotis). In cephalic features tomczykowae differs
from the type species T. (R.) rickardsi in having a transverse
rostral suture and strong medial indentation of the anterior
glabellar margin. In these respects tomczykowae is closest to
T. (R.) dyaulax.

The equal depth of pleural and ring furrows attained by
Trimerus ( Ramiotis ) tomczykowae is considered here to repre-
sent a significant stage of homalonotine development. This
feature distinguishes Wenlock-Ludlow T. (Ramiotis) from
Llandovery members of the group. Although in its short
pygidial proportions and rounded outline the affinities of
tomczykowae to Llandovery T. (Ramiotis) are clear, it repre-
sents a transitional morphology between these and Upper
Silurian species of T. (Ramiotis) and T. (Trimerus).

Indeterminate homalonotids from the Wenlock of
central Victoria include a partly disarticulated exoskeleton from
the old Tooronga Brick Pit, high in the Anderson Creek
Formation, only briefly examined by the author. The abundant
and diverse trilobite fauna occurring in the Bylands Siltstone at
PL206, Wallan has yielded only an single homalonotid thoracic
segment.

Environmental notes. Trimerus (Ramiotis) tomczykowae is a
very rare element of a moderately diverse fauna occurring in
the nodular mudstones of the Illaenus band. The fauna is dom-
inated by the blind illaenid Thomastus thomastus Opik, 1953.

Homalonotid trilobites from the Silurian and Lower Devonian

55

Together with Ananaspis typhlagogus the composition of the
fauna closely resembles a contemporary fauna from Argentina
described by Waisfeld and Sanchez (1993). The taphonomy of
the Illaenus band is characterised by an abundance of complete
exoskeletons of Thomastus in the ‘bumastoid stance’, pre-
sumed to be individuals preserved in their infaunal life position
(Sandford and Holloway, 1998). The taphonomy and the aute-
cology of Thomastus in the mudstones suggest a deeper water
environment for tomczykowae. Several specimens of tom-
czykowae occur in a richly fossiliferous sandstone presumably
interbedded within the mudstone, although the bed is not
known in outcrop.

Wenndorfia gen. nov.

Type species. Homalonotus mutabilis Koch, 1880 from the Lower
Devonian (upper Emsian) of Germany.

Other species included. Parahomalonotus angustico status

Tomczykowa, 1975, P. bostoviensis Tomczykowa, 1975, Digonus ele-
gans Tomczykowa, 1975, Homalonotus expansus Hector, 1876 (=H.
( Burmeisteria ) huttoni Allan, 1935, -D. margaritifer Wenndorf, 1990),
H. forbesi Rouault, 1855, Dipleura fornix Haas, 1968, Trimerus lily-
dalensis Gill, 1949, H. miloni Renaud, 1942, H. multicostatus Koch,
1883a, H. mutabilis Koch, 1880, T. novus Tomczykowa, 1975, H.
obtusus Sandberger and Sandberger, 1849, P. planus junior Wenndorf,
1990, H. planus Sandberger, 1849, U P. sp. nov. A” in Wenndorf, 1990,
“D. sp.” in Le Menn et al., 1976.

Range. Lower Devonian (Lochkovian-Emsian).

Diagnosis. Glabella of moderate height to very low, weakly
tapering. Lobation indistinct. Anterior margin of cranidium
U-shaped and more or less concentric with rounded anterior
margin of glabella, anterior branches of facial suture broadly
curved and strongly convergent anteriorly, rostral suture short
(tr.), transverse or continuous in curvature with anterior section
of facial suture. Eyes placed posteriorly, opposite 0.3-0.45
cephalic length. Sides of glabella more or less straight and
parallel, varying to strongly concave. Ventral surface of rostral
plate with low or prominent anterior node. Pygidial outline
parabolic with rounded tip, but triangular with pointed tip in
early species. Pygidium with axial furrows very shallow to
indistinct, axis without independent convexity, wide (0.4-0.65
time pygidial width anteriorly), strongly tapering (furrows con-
verging at 30-45°), not reaching margin but terminating at
about 0.85-0.95 times pygidial length, semicircular terminal
piece short (sag.), slightly raised, but often indistinct from
postaxial field.

Discussion. Wenndorfia has been erected to accommodate
many species previously assigned to Parahomalonotus (see
above). In establishing Parahomalonotus, Reed (1918) listed a
number of characters in the diagnosis that are not apparent in
the type species Homalonotus gervillei DeVerneuil, 1850 from
the Emsian of France. Reed described the “facial sutures
uniting in a regular wide arched commissure close to (the)
anterior margin” as diagnostic of the genus (Reed, 1918: 326).
However, in gervillei the anterior cranidial margin is quadrate,
the rostral suture being transverse and the anterior branches of
the facial sutures subparallel (see Pillet, 1973: fig. 120). Reed’s

original diagnosis also states a pygidial entire margin and more
or less indistinct trilobation as diagnostic. However, in con-
tradiction to these definitive parameters, trilobation is well
defined by the raised pygidial axis of gervillei, and the pos-
taxial ridge extends posteriorly as a short posteromedial spine
(see Pillet, 1973, pi. 37 fig. 5).

The revised diagnosis for Parahomalonotus s.s. (see above)
emphasises the distinctive features of P. gervillei, and hence
differs markedly from that given by Reed (1918). Of species
assigned to Wenndorfia, Reed assigned Homalonotus planus,
H. obtusus and H. multicostatus to Parahomalonotus with
question. In the course of their facial sutures and in pygidial
features, these species are in closer agreement with Reed’s
diagnosis of Parahomalonotus than with the type gervillei.
These species further differ from gervillei in having pygidial
axes that are much wider anteriorly, taper more strongly, are not
independently convex, lack postaxial ridges, and terminate
between 0.85 and 0.95 pygidial length, and glabellae that are
very low and lack distinct lobation.

Species included in Wenndorfia were previously assigned
variously to Digonus, Dipleura, Parahomalonotus and
Trimerus. Wenndorfia is most reliably distinguished from these
genera by the rounded outline of the anterior cranidial margin,
concentric to the strongly rounded glabellar anterior margin.
This morphology contrasts most strongly with the angular,
quadrate anterior cranidial margin of Digonus. In pygidial
morphology early representatives of Wenndorfia and Digonus
are alike, although marked differences between these groups
are manifest in later representatives in trends toward short,
rounded outlines, and elongate, triangular outlines with acute
processes respectively. Later representatives of Wenndorfia
further differ from Digonus in exhibiting moderately to
strongly concave glabellar sides.

Rostral morphology is recognised in this work as a reliable
character distinguishing Wenndorfia from Trimerus and
Dipleura. The rostral plate of Wenndorfia exhibits a diamond-
shaped outline and exhibits a variably developed antero-
medial node, whereas rostral plates of Trimerus and
Dipleura are elongate pentangular and pentangular in outline
respectively, and lack rostral processes.

Developmental trends in the pygidial morphology of
Wenndorfia, manifest in the replacement of triangular outlines
by rounded outlines in the mid-Pragian, are comparable to
developmental trends in Dipleura in the Late Silurian.
However, pygidia of species assigned to Wenndorfia vary
markedly in the depth of the pleural and ring furrows. In a
number of species the pleural and ring furrows are very shallow
to indistinct, and approach morphologies exhibited by species
of Dipleura. The distinction of these morphologically conver-
gent species relies on the course of the cephalic sutures, as dis-
cussed above (see Dipleura ). Pygidia of Trimerus ( Ramiotis )
and T. ( Trimerus ) are distinguished from the Wenndorfia
pygidial morphology in having a distinct postaxial ridge.

Wenndorfia mutabilis, unlike most other species of the
genus, is abundant and its dorsal and ventral morphology is
both completely known and recently redescribed (see
Wenndorf, 1990). The species exhibits the rounded anterior
cranidial margin, the weakly expressed pygidial trilobation and

56

Andrew C. Sandford

the entire pygidial margin included in Reed’s original diag-
nosis of Parahomalonotus and in the diagnosis of Wenndorfia.
Other features exhibited by mutabilis and considered typical
of Wenndorfia include the strongly rounded anterior margin of
glabella, the posteriorly placed eyes, the small node on the
ventral surface of rostral plate, and the wide, strongly tapering
axis terminating at about 0.85 pygidial length. W. mutabilis is
distinguished from its congeners in having a glabella of moder-
ate height with strongly concave sides, a wide palebral area,
and a shorter pygidial outline with shallow pygidial ring and
pleural furrows.

Lochkovian-lower Pragian Wenndorfia differ from upper
Pragian-Eifelian species in variously exhibiting features that
can be regarded as underived. These features include a
trapezoid glabellar outline, the expression of glabellar lobation,
moderately impressed pygidial axial furrows, deep pleural and
ring furrows, and a triangular pygidial outline with an obtusely
angled tip. In these respects these early species represent a
transitional morphologies with early Digonus. Early represen-
tatives of Wenndorfia include several Polish homalonotids orig-
inally described as species of Digonus by Tomczykowa (1975)
and regarded by Wenndorf (1990) as representing an early
Digonus morphology. Lacking in these Polish species is the
quadrate anterior cranidial outline exhibited by the earliest
Digonus (see above, D. wenndorfi). The strongly rounded
anterior glabellar margin, the concentric cranidial margin and
posteriorly placed eyes indicate assignment of these species to
Wenndorfia. The upper Lochkovian W. bostoviensis from
Poland is the earliest species assigned to Wenndorfia.
W. bostoviensis differs from W. mutabilis and other Wenndorfia
in having and a short triangular pygidial outline. This pygidial
morphology suggests affinities of the earliest Wenndorfia to the
earliest Digonus.

Tomczkowa (1975) assigned homalonotids from upper
Lochkovian-lower Pragian strata immediately overlying
Wenndorfia bostoviensis to Digonus vialai. The number of
specimens representing these two morphologies is limited, with
four cranidia representing vialai and two representing
bostoviensis. Tomczkowa distinguished vialai from bostov-
iensis by its trapezoid rather than rectangular glabellar outline,
but the significance of these supposed differences cannot be
determined without reference to larger populations. In all other

respects it is difficult to distinguish vialai from bostoviensis,
and the specimens are best considered conspecific. Similarly,
Tomczykowa described Parahomalonotus angustico status
from the lower Pragian of Poland using a limited collection of
pygidia, only one complete. Tomczykowa (pi. 6 figs 1-4)
assigned pygidia from a slightly lower horizon to
Parahomalonotus forbesi (Rouault, 1855), distinguished from
those of angusticostatus in having fewer axial rings and ribs
and shallower pleural and ring furrows. However, the pygidia
figured do not differ markedly from angusticostatus and are
considered to be conspecific.

Wenndorfia expansa (Hector, 1876)

Figure 22.7-22.14

Homalonotus expansus Hector, 1876: 602, pi. 27 fig. 2.

Homalonotus sp. — Hutton, 1888: 257.

Homalonotus (Burmeisteria) huttoni. — Allan, 1935: 28, pi. 1 figs
4-5.

Homalonotus (Digonus) expansus. — Allan, 1935: 29, pi. 1 fig. 1.

Homalonotus ( Digonus ) cf. expansus. — Allan, 1935: 29, pi. 1 fig. 3.

Burmeisteria ( Digonus ) expansus. — Saul, 1965: 271.

Burmeisteria huttoni. — Saul, 1965: 271. — Tomczykowa, 1975: 11.

Digonus expansus. — Tomczykowa, 1975: 11. — Wenndorf, 1990:
16.

Burmeisteria ( Digonus ) cf. expansus. — Speden and Keyes, 1981:
pi. 4 fig. I.

Burmeisteria expansa. — Cooper, 1982: 27.

Burmeisteria huttoni. — Cooper, 1982: 27. — Wenndorf, 1990: 16.

Digonus margaritifer — Wenndorf, 1990: 77, pi. 11 figs 8-9.

Type material. Homalonotus expansus. Lectotype (pygidium, figured
Hector, 1876, Allan, 1935: pi. 1 fig. 1, Fig. 22.10 herein, in the
Geological Survey of New Zealand, cast in Museum Victoria regis-
tered NMV PI 6844) from McKay locality 129, Rainy Creek, Reefton,
south island, New Zealand. Paralectotype (pygidium, also the holotype
of Digonus margaritifer, figured Allan, 1935: pi. 1 fig. 3, Wenndorf,
1990: pi. 11 fig. 8, in the Geological Survey of New Zealand, cast in
Museum Victoria registered NMV PI 6846) from McKay locality 130,
LankeyGully, Reefton. Paralectotype (pygidium, figured Hector, 1876,
in the Geological Survey of New Zealand, cast in Museum Victoria
registered NMV P16847) from locality 129.

Homalonotus (Burmeisteria) huttoni. Holotype ZFc33 (dorsal
exoskeleton, figured Allan, 1935: pi. 1 figs 4, 5) from “near Reefton”.
Allan (1935) suggested the specimen is from locality 129.

Figure 22. 1-22.6. Digonus wenndorfi sp. nov. 1, paratype NMV P304713, cranidium, dorsal view x 1.4 (internal mould) from PL2203. 2, paratype
NMV P304862, pygidium, dorsal view x 1.5 (internal mould) from PL2203. 3a, paratype NMV P304864, pygidium, posterior view x 1.35
(internal mould) from PL2203. 3b, same, lateral view x 1.25. 4, paratype NMV P304866, pygidium, dorsal view x 1.25 (internal mould) from
PL2203. 5, paratype NMV P304710, cranidium, dorsal view x 1.0 (internal mould) from PL2203. 6, paratype NMV P304717, pygidium,
posterior view x 1.15 (internal mould) from PL2203.

Figure 22.7-22.14. Wenndorfia expansa (Hector, 1876). 7a, holotype of Homalonotus ( Burmeisteria ) huttoni Allan, 1935, ZFc 33, enrolled
exoskeleton, dorsal view of pygidium x 0.7 (internal mould) from near Reefton (exact locality unknown). 7b, same, lateral view of enrolled
exoskeleton. 7c, same, dorsal view of cephalon. 7d, same, posterior view of enrolled exoskeleton. 8a, NMV P64122, pygidium, dorsal view x 0.9
(internal mould) from “Reefton”. 8b, same, posterior view. 9, paralectotype of Homalonotus expansus Hector, 1876 and holotype of Digonus
margaritifer, pygidium, dorsal view x 0.9 (internal mould) from locality 130, Reefton (NMV P16846, plastercast of original). 10a, lectotype of
Homalonotus expansus Hector, 1876, pygidium, dorsal view x 1.15 (internal mould) from locality 129, Reefton (NMV P16844, plastercast of
original). 10b, same, external mould. 11, paralectotype of Homalonotus expansus Hector, 1876, pygidium, dorsal view x 0.7 (internal mould) from
locality 129, Reefton (NMV P16847, plastercast of original). 12, NMV P64121, pygidium, dorsal view x 1.23 (internal mould) from “Reefton”.
13, NMV P64120, pygidium, dorsal view x 0.95 (internal mould) from “Reefton”. 14, ZFc 58, incomplete thoracopygon, dorsal view x 0.75
(internal mould) from “Reefton”.

58

Andrew C. Sandford

Digonus margaritifer. Holotype (pygidium, and paralectotype of
Homalonotus expansus , see above). Paratype (pygidium, figured
Wenndorf, 1990: pi. 11 fig. 9, in the Palaontologisches Museum der
Humboldt-Universitat Berlin, Germany), documented as coming from
Kilmore, Victoria, acquired through the fossil dealer Kranz in 1885.
However as the paratype is undoubtedly conspecific with the New
Zealand material, as no homalonotids other than Trimerus ( Trimerus )
vomer , Trimerus ( Ramiotis ) otisi and Dipleura garratti are yet known
in the well-collected Wenlock-Ludlow trilobite faunas from the
Kilmore area, and as Wenndorfia would be most unexpected in strata
of this age, I conclude that the Berlin specimen is from the Reefton
area and its documentation confused, possibly by Kranz, with a
specimen of T. (T.) vomer. Kranz may have acquired the Berlin
specimen from Theodore Ranft who was the first to collect fossils in
Lankey Gully at Reefton in 1872. Part of Ranft’s collection was
purchased by the Melbourne Museum, who also had dealings with
Kranz.

Previously figured material. NZGS AR 676 (thoracopygon, figured
Speden and Keyes, 1981: pi. 4 fig. I) from locality GS3737, S38/f523,
Rainy Creek, Reefton.

Registered material. 12 specimens: 1 complete exoskeleton, 2 thora-
copygons, 1 incomplete thorax, 8 pygidia,. NMV PI 6844, NMV
P16847 from locality 129. P16846 from locality 130. NZGS AR676
from locality GS3737. NMV P64120-P64122 from Lankey Gully
(Ranft collection). ZFc33, ZFc58, ZFc309, ZFc350 from “Reefton”.
One pygidium in the Palaontologisches Museum der Humboldt-
Universitat Berlin.

Stratigraphic distribution. Lankey Limestone, IBoucotia loyolensis
Assemblage Zone, Emsian.

Diagnosis. Glabella extremely low, sides parallel, without dis-
tinct lobation, anterior margin broadly rounded, length 1.1
times width. Palpebral lobes placed opposite -0.55 glabellar
length. Axial furrows very poorly defined. Pygidium short,
with length 0.7 times width, weakly concave sides, converging
posteriorly at about 100° to an obtusely angular tip. Pygidial
axis wide, about 0.4 times pygidial width and very poorly
defined anteriorly, tapering moderately with sides straight and
converging at about 30°, length about 0.85 times pygidial
length, posterior margin parabolic, 12-13 rings, semicircular
terminal piece with distinct posterior margin. Axial furrows
poorly defined, indicated by flexure of pleurae, almost indis-
tinct anteriorly. 9 pleural ribs. Pleural furrows not reaching
margin. Pleural and ring furrows deep and of equal depth.
Anteriorly ribs and rings continuous, pleural offset at seventh
rib. Row of equidimensional, regularly spaced tubercles on
axial area of thoracic and pygidial segments, with two or three
supplementary rows of smaller tubercles. Tubercles large on
larger specimens, small to fine on smaller specimens. Similar,
but less regular tuberculation on posterior border of fixigenae
and thoracic and pygidial pleurae. Genal field with densely
spaced, coarse granules.

Discussion. Three homalonotids have been named from the
Lower Devonian at Reefton. The best known of these is
Homalonotus ( Burmeisteria ) huttoni, based on a single, near-
complete, enrolled exoskeleton (Fig. 22.7). The specimen was
described in detail in open nomenclature by Hutton (1888), and
later named by Allan (1935). Several points in Hutton’s
original description of the specimen cannot be substantiated, in

particular those concerning the cephalic shape and proportions,
and the presence of distinct glabellar lobation. Although only
the first six segments of the pygidium are preserved in the holo-
type, the ornament of tubercles on the pleural ribs and axial
rings are distinctive and shared by several more completely
preserved pygidia in the Museum of Victoria (NMV P64 120-2,
Figs 22.8, 22.12-22.13) and in the New Zealand Geological
Survey (NZGS AR 676, Fig. 22.14). These pygidia also share
very deep ring and pleural furrows that are continuous to the
seventh segment. The axial furrow is not impressed on the
anterior half of the pygidium, but its position is indicated by a
posteriorly increasing flexure at the junction of the ring
and pleural furrows. These specimens are considered to be
conspecific with the holotype of huttoni.

The other two species, Homalonotus expansus and Digonus
margaritifer, were based only on pygidia. Wenndorf ’s (1990)
description of margaritifer includes features identical with
those of H. (. Burmeisteria ) huttoni, such as the ornament, the
deep axial ring and pleural furrows continuous to the seventh
rib, the very shallow axial furrows, and the wide rounded-
triangular outline. Wenndorf noted expansus and margaritifer
shared pleural offsetting at the seventh-eighth rib, but distin-
guished the former by the smooth surface texture (absence of
tubercules) and the weak definition of the axis of the former
species. Close inspection of the external mould of the lectotype
of expansus reveals, however, a row of small tubercles on the
first four axial rings and pleurae (see Fig. 22.10b).
Corresponding ornament on the anteriormost rings on the
internal mould were not recorded either by Hector (1876) or by
Allan (1935) as this area of the pygidium is damaged. The
spacing of these tubercles on the lectotype is similar to that of
huttoni. The differences in the coarseness of tuberculation
between the type specimens of expansus and specimens of
huttoni are attributed here to the size of the pygidia. The
lectotype of expansus, with the finest tubercles, is the smallest
specimen. Moderately sized specimens including the
holotype of margaritifer have slightly larger tubercles (see Fig.
22.9), whereas the largest of specimens including the
holotype of huttoni have much larger tubercles. This interpreta-
tion is in accord with Cooper’s (1982) suggestion that
expansus and huttoni might be synonyms. The differences in
definition of the axis between margaritifer and expansus
noted by Wenndorf (1990) can be attributed to the flattening
of the lectotype of expansus, axial convexity obscured by
crushing and longti-tudinal folding of the tergite. Taking this
deformation into account, whatever differences may have
existed between the specimens do not appear to be significant.
In the absence of significant differences in ornament
or other features between the types of expansus and pygidia
of margaritifer and huttoni, the species are regarded as
conspecific.

There is little to support the assignment of Homalonotus
expansus to Burmeisteria. The most reliable character of
Burmeisteria recognised in this work is the exceptionally high
number of pygidial segments, with B. herschelii having up to
17 axial rings and 11 pleural furrows. H. expansus has only 12
axial rings and 9 pleural ribs. Reed (1918) emphasised the
biconcave course of the rostral suture in herschelii as a generic

Homalonotid trilobites from the Silurian and Lower Devonian

59

character. Cooper (1982) suggested the course of the rostral
suture of herschelii to be variable and probably ontogenetic-
ally related, supporting earlier doubts on its significance
(Sdzuy, 1957, Saul, 1965). Notwithstanding this debate, the
anterior portion of the cephalon (and the rostral suture) of the
holotype of huttoni is not preserved. B. herschelii is strongly
polymorphic, with variable glabellar morphology, but the
glabella of expansus differs in having no trace of lobation or
spines, and in that the axial furrows are subparallel and much
shallower. In the absence of rostral morphology, the assignment
of huttoni to Burmeisteria by various workers (Allan, 1935,
Wenndorf, 1990) was presumably based on the similarity of
the tuberculate ornament to that of herschelii. The arrange-
ment of these tubercles suggests, however, they are not homo-
logous, but independently derived. As noted by Cooper (1982),
the tubercules of herschelii are arranged longitudinally. This
arrangement differs from the transversely arranged tubercles on
expansus.

Tuberculation similar to that exhibited by Homalonotus
expansus is known amongst members of Digonus. Wenndorf
(1990) noted a close similarity in pygidial ornament between
the paratypes of margaritifer and the ornatus group. Wenndorf
added that margaritifer shared few other ornatus- group
characters. The narrow pygidial axis is incompatible with
assignment of expans a to Digonus.

Generic assignment of Homalonotus expansus to
Wenndorfia emphasises its low glabellar height, rounded anter-
ior glabellar margin, posteriorly placed eyes, indistinct
pygidial axial furrows and narrow axial width, and the contin-
uity of the ring and pleural furrows, the termination of the axis
at about 0.9 pygidial length, and the absence of a postaxial
ridge. Its relationships to other species of Wenndorfia are diffi-
cult to assess, but it differs from all other species in exhibiting
a coarsely tuberculate thoracic and pygidial ornament. In over-
all appearance, pygidia assigned to W. expansa most closely
resemble the deeply furrowed pygidia of W. multicostata. The
triangular pygidial outline, however, distinguishes it from
multicostata and most other Wenndorfia, as discussed above.
As the cephalic morphology of multicostata is poorly known, it
is difficult to make a detailed comparison with expansa. The very
low height and poor definition of the glabella of expansa is
approached only by W. plana plana, although the latter differs
in that the glabellar axial furrows are quite distinct posteriorly.

Shirley (1938) recorded Homalonotus sp. from the Baton
Formation at Baton River, east of Nelson, North Island, New
Zealand. He considered ten crushed and deformed pygidia to be
identical with pygidia of Wenndorfia expansa. Shirley’s
description of the number of axial rings and pleural ribs and the
continuity of the rings and pleurae are in accord with expansa,
but as I have not examined these specimens I can make no
judgement on their affinities. The Baton Formation is gener-
ally considered younger than the Lankey Limestone at Reefton,
although its age is variably cited as Pragian (Boucot et al.,
1969) or Lochkovian (Wright, 1990).

The newly documented material warrants a revised diagno-
sis of the species, but otherwise is too limited to warrant a com-
plete description to replace those of Hutton (1888), Allan
(1935) and Wenndorf (1990).

Figure 23. Geological sketch map of the Lily dale area showing
Lochkovian-basal Pragian fossil localities yielding homalonotids. For
other fossil localities see also Gill (1940, fig. 1, 1945, fig. 2), Moore
(1965, fig.l), VandenBerg (1970), Garratt (1972), Wall et al. (1995,
fig. 1), Sandford (2003, text-fig. 1A, 2004, fig. 1).

60

Andrew C. Sandford

Environmental notes. The taphonomy of the population of
Wenndorfia expansa (as a whole) are attributable to Speyer and
Brett’s taphofacies 4B, with Ar=33% and the relative
abundance of completely enrolled specimens (8%). W. expansa
is interpreted to inhabit deep, outer-shelf environments. This
suggested habitat is comparable to the deepest water facies
associated with populations of many other species of
Wenndorfia (see Wenndorf, 1990)

Wenndorfia lilydalensis (Gill, 1949)

Figures 5C, 24

Homalonotus harrisoni. — Cresswell, 1894: 156.

Homalonotus sp. — Chapman, 1907: 239. — Gill, 1938: 170.
Trimerus lilydalensis Gill, 1949: 69, pi. 8 figs 4-5, pi. 9 fig. 7,
text-fig. IF — Holloway and Neil, 1982: 145.

Type material. Holotype NMV P14587 (cephalon, figured Gill, 1949:
pi. 8 figs 4-5, text-fig. IF, Fig. 24.1 herein, counterpart previously
registered NMV P14588) from PL1801, Gill locality 1, Mooroolbark,
Victoria. Paratype NMV PI 45 89 (pygidium, figured Gill, 1949: pi. 9
fig. 7) from PL1801. For locality see Fig. 23.

Registered material. 57 specimens: 1 articulated dorsal exoskeleton, 1
disarticulated dorsal exoskeleton, 1 enrolled cephalothorax, 9 cephala,
7 cranidia, 3 librigenae, 12 thoracic segments, 23 pygidia. NMV
P304527 from PL1805, Gill locality 5, Coldstream, Victoria. NMV
P304531, P304532 from PL1990, Coldstream. NMV P304528-
P304530 from PL1813, Gill locality 13, Mooroolbark. NMV
P304524-P304526 from PL 1887, Gill locality 87, Mooroolbark. NMV
P3204533, NMV P304570 from PL1869, Gill locality 69,
Mooroolbark. NMV P304549-P304558 from PL1801. NMV P304567,
P304569 from PL6661, Lilydale, Victoria. NMV P457, NMV
P304559-P304562 from PL1802, Gill locality 2, Lilydale. NMV
P3045 1 6-P3045 1 8 from PL1810, Gill locality 10, Lilydale. NMV
P304522 from PL1858, Gill locality 58, Lilydale. NMV P304534-
P304548, NMV P304566 from PL1859, Gill locality 59, Lilydale.
NMV P304523 from PL 1862, Gill locality 62, Lilydale. NMV
P304520, P304521 from PL 1829, Gill locality 29, Kilsyth, Victoria.
NMV P304563-P304565 from “Lilydale”. NMV P304519 from “with-
in 1 km of Mooroolbark Railway Station”. NMV P304571 probably
from the Lilydale area. For localities see Fig. 23.

Stratigraphic distribution. Humevale Siltstone, from 1750 m above the
base of the unit up to a horizon 3700 m above the base of the unit,
upper Boucotia australis Assemblage Zone to lower Boucotia
loy-olensis Assemblage Zone, late Lochkovian-earliest Pragian.

Diagnosis. Cephalon weakly pentangular in outline, with
length 0.56 times width. Glabellar length equalling width, sides

straight, weakly tapering (15°), strongly rounded anteriorly.
Glabellar lobation weakly defined. Palpebral lobe placed with
midline opposite 0.5 cranidial length. Preglabellar field
(excluding rostral plate) 0.15 times cranidial length. Anterior
cranidial margin evenly rounded, concentric with glabellar
anterior margin. Dorsal surface of rostral plate crescentic in
shape, length (sag.) 0.05 times cephalic length, anterior margin
obtusely angular (130°). Ventral surface of rostral plate wide,
kite-shaped, width 1.15 times length. Pygidium triangular,
length 0.8 times width, tip obtusely pointed (-100°). Axis very
wide anteriorly, width 0.66 times pygidial width, length 0.92
times pygidial length, sides straight. 9-11 axial rings, 8 pleural
ribs, ring and pleural furrows deep. Surface of cephalon with
fine tubercles, more distinct and densely distributed adjacent to
the cephalic margin.

Description. Exoskeleton with maximum size moderate (estimated 20
cm from NMV P304562).

Cephalon with pentangular outline, sides converging forwards at
70-75° opposite glabella and at about 135° opposite preglabellar field,
length about 0.57 times width. Glabella with length 0.75 times
cephalic length, width 0.45 times cephalic width, sides converging at
13-17°, length ranging between 1.06-0.91 times width. Occipital ring
length 0.1 times cranidial length, slightly wider medially. Occipital
furrow deep on internal moulds, shallow on external moulds, weak
forward flexure medially. Glabellar anterior margin well defined, with
arc of curvature centred at 0.55 times glabellar length. Glabella weak-
ly convex (tr., sag.). Glabellar lobation very weakly defined (best seen
on NMV P304562 and NMV P304516, Figs 24.2, 24.4), LI 0.22 times
glabellar length, L2 and L3 0.11 times glabellar length. S3 transverse,
S2 directed inwards-backwards at about 7° from the transverse and S 1
at 15° from the transverse. Axial furrows wide, shallow posteriorly,
moderately impressed anteriorly, paraglabellar areas poorly defined.
Preglabellar field of uniform width, flat. Length (exsag.) of posterior
border equal to occipital length abaxially, lengthening adaxially to 2.0
times occipital length. Posterior border furrow transverse, shallow and
very wide, meeting lateral border furrow distally. Postocular fixigenal
area short, length (exsag.) 0. 14 times cranidial length. Palpebral lobe
0.13 times cranidial 1.75 times preoccipital glabellar width, very
shallow 6-6 length, palpebral furrow. Preocular fixigena area wide,
0.22 narrowing forwards anteriorly. Anterior branches of facial suture
broadly curved, meeting connective sutures almost at margin opposite
0.9 cephalic length. Librigena with wide, moderately impressed
border furrow, librigenal area weakly convex, steeply inclined, lateral
border wide and convex, shallow, wide subocular furrow. Dorsal
surface of rostral plate slightly inclined (in lateral view, see Figs 24.2c,
24.3c), length (exsag.) 0.18 times width (tr.). Ventral surface of rostral
plate kite-shaped, with slightly medial flexure (tr.) giving anterior

Figure 24. Wenndorfia lilydalensis (Gill, 1949). la, holotype NMV P14587, cephalon, dorsal view x 2.3 (latex cast) from PL1801. lb, same,
oblique view x 2.5. lc, same, dorsal view x 1.8 (internal mould). 2a, NMV P304516, cephalon and displaced thoracopygon, dorsal view, enlarge-
ment of anterior margin of cephalon x 5.0 (latex cast) from PL1810. 2b, same, dorsal view of cephalon x 1.5 (internal mould). 2c, same, oblique
view of cephalon x 1.4 (latex cast). 2d, same, dorsal view of thoracopygon x 1.3 (latex cast). 3a, NMV P304536, cephalon, ventral view (dou-
blure) x 2.2 (latex cast) from PL1859. 3b, same, dorsal view x 2.25. 3c, same, lateral view x 2.55. 4, NMV P304562, cephalon, dorsal view x 2.2
(internal mould) from PL1802. 5, NMV P304531, cephalon, ventral view (doublure) x 3.3 (latex cast) from PL1990. 6, NMV P304528, cephalon,
dorsal view x 1.3 (latex cast) from PL1813. 7, NMV P304550, pygidium, dorsal view x 1.4 (internal mould) from PL1801. 8a, NMV P304565,
pygidium, posterior view x 2.9 (latex cast) from “Lilydale” 8b, same, dorsal view. 8c, same, lateral view. 9, NMV P304534, pygidium, dorsal
view x 2.2 (internal mould) from PL1859. 10, paratype NMV P14589, pygidium, dorsal view x 2.1 (internal mould) from PL1801. 11a, NMV
P304549, pygidium, lateral view x 1.6 (internal mould) from PL1801. lib, same, dorsal view (latex cast). 12, NMV P304566, pygidium, ventral
view (doublure) x 2.8 (internal mould) from PL1859. 13, NMV P457, pygidium, dorsal view x 1.5 (internal mould) from PL1802. 14, NMV
P304550, pygidium, dorsoposterior view x 1.7 (internal mould) from PL 1801.

Homalonotid trilobites from the Silurian and Lower Devonian

61

62

Andrew C. Sandford

margin of cephalon a very weak M-shaped outline, flat posteriorly.
Connective sutures weakly sinusoidal, diverging at 90° posteriorly and
at 50° anteriorly. Posteriorly, connective sutures are either confluent
immediately anterior to the meeting the hypostomal suture (NMV
P304536, Fig. 24.3a), or meet the hypostomal suture separately (NMV
P304531, Fig. 24.5).

Thorax with 13 segments. On external moulds axial furrows and the
pleural flexure are not defined, although the axis is marked on internal
moulds by exsagittal line of deep depressions (axial articulating
processes) on the posterior margin of each segment. Pleural furrows
wide and deep, pleural tips rounded.

Pygidium with sides weakly and uniformly convex. Axial furrows
converging at about 45°, indistinct opposite first and second rings,
shallow posteriorly. Axis poorly defined posteriorly without postaxial
ridge. Pleural furrows not reaching margin, border poorly defined and
lacking independent convexity from pleural field, without border
furrow. In posterior view anterior margin strongly convex, posterior
margin weakly arched to accommodate rostral flexure. In lateral view
dorsal margin steep (-45°) and gently curved, ventral margin more or
less horizontal.

Discussion. Trimerus lilydalensis exhibits several features
indicative of assignment to Wenndorfia, including the strongly
rounded anterior glabellar margin and the concentric anterior
cranidial margin, the antero-medial rostral node, the weak
pygidial trilobation, and the termination of the pygidial axis at
about 0.9 pygidial length. The species was originally described
from a limited number of poorly preserved specimens, but is
redescribed from a much larger population.

Gill’s (1949) description of the species includes several of
the diagnostic characters listed above, although the revised
diagnosis differs in a number of points. Gill described the
cephalon as being markedly inflated (it is only moderately
convex, see Fig. 24.2c), and the exoskeleton as being smooth
(it bears fine tubercules and pits, see Fig. 24.2a).

Holloway and Neil (1982) considered specimens of Digonus
wenndorfi from the Heathcote area to be possibly conspecific
with Wenndorfia lilydalensis. W. lilydalensis can be easily
distinguished from wenndorfi in having pygidia lacking a
raised postaxial ridge, and cranidia with a U-shaped rather than
quadrate anterior margin, a more weakly tapered glabella with
a more rounded anterior margin, and a forwardly convex rather
than transverse rostral suture.

Wenndorfia lilydalensis is most closely comparable to the
contemporary W. bostoviensis from the upper Lochkovian of
Poland. The species share a similar trapezoid, moderately
tapering, straight-sided glabellar outline and a very wide (tr.)
palpebral area. Glabellar lobation is variably expressed in
lilydalensis, and although Tomczykowa (1975) noted an
absence of glabellar lobation for bostoviensis, shallow SI -S3
can be seen on specimens considered here to be con-
specific with bostoviensis (see discussion above). More
significantly, bostoviensis also exhibits a relatively underived
pygidium, with a triangular pygidial outline with an acutely
angled tip. Pygidial axial furrows are moderately impressed
on bostoviensis, distinguishing it from lilydalensis and younger
species of Wenndorfia, that share very shallow to effaced
pygidial axial furrows. The only other Wenndorfia to exhibit a
triangular pygidial outline is the lower Pragian Polish W. nova,
with less elongate pygidial proportions and a very narrow

pygidial axis. In cranidial morphology nova shows some
resemblance to lilydalensis, although the former differs in
having narrow palpebral areas.

Wenndorfia lilydalensis is confined to the Lilydale
sequence. One specimen labelled as coming from the Seville
area, collected by F. Chapman, was found to have a counterpart
labelled as coming from the Lilydale area, collected by
J. Jutson. The lithology of the specimen matches lithologies
from the Lilydale sequence rather than those from Seville.
Gill’s (1938) record of the species from PL 1835, Gill locality
35, Seville is also probably erroneous, as the lithology of the
specimen is unlike that at PL1835, but again closely matches
lithologies of the Lilydale sequence.

Environmental notes. The faunal associations of Wenndorfia
lilydalensis are complex. W. lilydalensis first appears as a rare
element in the trilobite fauna (relative abundance 2%), but
through its range steadily increases in relative abundance,
reaching maximum relative abundance in the upper horizons of
its range. In the lower part of its range lilydalensis frequently
occurs in phacopid-dominated assemblages, but in the upper
parts of its range lilydalensis is frequently part of a distinct
acastid/homalonotid dominated association

With the exception of a complete exoskeleton from a bio-
clastic coquinal sandstone at PL 1805 (taphofacies Till), all
specimens of Wenndorfia lilydalensis are found in a siltstone
lithology preserved as isolated sclerites or partly disarticulated
specimens including cephala, a cephalon with 7 thoracic
segments, and a moult assemblage, being a cephalon lying
obliquely over the thorax. A cranidium and nearby pygidium on
the same bedding plane might also be interpreted as a moult
assemblage (taphofacies TIV). An outer shelf setting is sug-
gested as the preferred environment of W. lilydalensis, which
ranges only as a rare faunal element to mid shelf settings and to
even deeper settings where it occurs with a calymenid-
phacopid association. The taphonomy of the latter, with a high
degree of articulation and containing sparsely distributed moult
assemblages and rare enrolled specimens represents a new
taphofacies for central Victoria, designated taphofacies TV,
equivalent to Speyer and Brett’s (1986) taphofacies 4B (see
Fig. 6).

Acknowledgements

I extend my sincere thanks to Dr Alan Thomas (University of
Birmingham) and to an anonymous referee for their most
detailed and helpful reviews of the manuscript, and for alerting
me to a number of publications on British homalonotids which
I had overlooked. Research for this work was funded from an
Australian Postgraduate Award. I gratefully acknowledge Dr
David Holloway (Museum Victoria), Dr Malcolm Wallace
(University of Melbourne) and Dr Stephen Gallagher
(University of Melbourne) for their supervision of this project.
Mr Peter Duncan (Eden Park) kindly donated specimens of
Trimerus ( Ramiotis ) otisi collected from his property. I also
thank Dr Norton Hiller, Canterbury Museum, Christchurch,
New Zealand for the loan of specimens of Wenndorfia expansa
including the holotype of Homalonotus ( Burmeisteria ) huttonv.

Homalonotid trilobites from the Silurian and Lower Devonian

63

and Mr Robert Jones at the Australian Museum for the loan of

a well-preserved cranidium of Trimerus ( Trimerus ) harrisoni ,

regretfully lost.

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Memoirs of Museum Victoria 62(1): 67-89 (2005)

ISSN 1447-2546 (Print) 1447-2554 (On-line)
http://www.museum.vic.gov.au/memoirs/index.asp

Pliocene marine mammals from the Whalers Bluff Formation of Portland,
Victoria, Australia

Erich M.G. Fitzgerald

School of Geosciences, Monash University, Vic. 3800, Australia and Museum Victoria, G.P.O. Box 666, Melbourne, Vic.
3001, Australia (efitzger@museum.vic.gov.au)

Abstract Fitzgerald, E.M.G. Pliocene marine m a mmals from the Whalers Bluff Formation of Portland, Victoria, Australia.

Memoirs of Museum Victoria 62(1): 67-89.

The most diverse and locally abundant Australian fossil marine mammal assemblages are those from late Neogene (Late
Miocene through Late Pliocene) sediments in Victoria and Flinders Island, Tasmania. However, none of these
assemblages have hitherto been described. The Pliocene (>2.5^1. 8 Ma) Whalers Bluff Formation, exposed in beach cliff
sections and offshore reefs, at Portland, western Victoria (38°19'S, 141°38'E) has yielded a small but moderately
diverse assemblage of marine mammals represented by fragmentary material. Taxa present include: right whales
(Balaenidae); rorqual whales (Balaenopteridae); a physeterid similar to the extant sperm whale (cf. Physeter sp.); the first
Australian fossil record of pygmy sperm whales (Kogiidae); at least three genera of dolphins (Delphinidae: cf. Tursiops
sp., Delphinus sp. or Stenella sp., and an undetermined genus and species); and probable earless or tme seals (Phocidae).
This small assemblage represents the first Australian fossil marine mammal assemblage to be described in detail. The
taxonomic composition of this Pliocene marine mammal assemblage is generally similar to the present day marine
mammal assemblage in north-west Bass Strait. The occurrence of extant cetacean genera in the Portland Pliocene and
Blinders Island Cameron Inlet Formation assemblages indicates that the marine m a mmal fauna off south-east Australia
had acquired an essentially modern aspect by the Late Pliocene. Several of the cetacean genera recorded in the Portland
Pliocene assemblage also occur in similar-aged assemblages in other ocean basins. This corroborates the hypothesis that
many cetacean taxa that are widely distributed in the world’s oceans today were equally widespread during the Pliocene.

Keywords Cetacea, Carnivora, Pinnipedia, Phocidae, Mysticeti, Odontoceti, Australia, Victoria, Portland, Whalers Bluff Formation,

Pliocene

Introduction

The Pliocene epoch (1.8-5. 3 Ma) is generally considered to be
the time during which the modem marine mammal fauna
evolved, with the extinction of archaic taxa (as well as some
taxa with novel adaptations), and widespread geographic
distribution of extant families and genera (Bames, 1977;
Fordyce, 1989; Fordyce and Barnes, 1994; Fordyce and
Muizon, 2001; Fordyce et al., 2002; Demere et al., 2003).
Although the Pliocene marine mammals of the North Pacific
(e.g. Barnes, 1973a, 1977, 1998) and eastern tropical
Pacific (e.g. Muizon, 1981, 1984; Muizon and DeVries, 1985;
Muizon and Domning, 1985, 2002) have been described and
discussed in some detail, the Pliocene marine mammals of
the Southwest Pacific (Australia and New Zealand) remain
poorly known (Fordyce et al., 2002: 53). This is despite the fact
that Australian late Neogene marine mammals (mostly
cetaceans) are relatively abundant in museum collections,

especially the Palaeontology Collections of Museum Victoria,
Melbourne.

The majority of Pliocene marine mammal fossils in these
collections are rather fragmentary with one partially complete
skull and associated skeleton known (NMV PI 79005, cf.
Megaptera sp.). Despite this general lack of diagnostic skull
material, some details of the SW Pacific Pliocene marine
mammal fauna may be filled in by the study of certain isolated
skeletal elements such as periotics. As noted by Bames (1977:
322), study of these isolated elements may provide data on the
taxonomic diversity within an assemblage and wider fauna.
Pliocene marine mammal assemblages have hitherto not been
described from Australia, so descriptions of even fragmentary
material provide an initial basis for understanding marine
mammal evolution off southern Australia during the Pliocene.
This description of marine mammals from the Pliocene Whalers
Bluff Formation assemblage comprises a preliminary basis for
the late Neogene fossil record of marine mammals in Australia.

Erich M.G. Fitzgerald

Figure 1. Locality of Portland in Victoria, south-east Australia, and the Portland fossil marine vertebrate localities. Fossils have been collected as
float along the beach and from adjacent cliffs between Dutton Way and Portland Harbour. Black shading indicates areas of cliff outcrop of the
Whalers Bluff Formation.

Pliocene marine mammals

All fossils were collected from coastal exposures of the
Whalers Bluff Formation lining Portland Bay in western
coastal Victoria, southeast Australia (38°19'S, 141°38'E)
(Fig. 1). Unfortunately, details of the geological context of vir-
tually all fossils are unknown apart from whether the fossils
were collected from the Whalers Bluff Formation or underlying
limestone. Fitzgerald (2004a, 2004b) mentioned the Portland
fossil marine mammals in previous publications. Bearlin (1987:
177) briefly noted the occurrence of cf. Balaena sp., and cf.
Balaenoptera sp. in private collections in an unpublished Ph.D.
thesis. The vertebrate faunal list for Portland given by
Fitzgerald (2004b: 186) was completed prior to the recognition
of two distinct, stratigraphically/temporally disjunct marine
vertebrate assemblages at Portland. The majority of the verte-
brates listed by Fitzgerald (2004b) were derived from the
Pliocene Whalers Bluff Formation although some vertebrates
from the Portland Late Miocene assemblage were listed under
the Whalers Bluff Formation assemblage. The Portland Late
Miocene marine vertebrate assemblage, from the Port
Campbell Limestone, is considerably more diverse than the
Pliocene Whalers Bluff Formation assemblage, and is to be
described in a subsequent publication. Below is an emended list
of the vertebrates recorded in the assemblage from the Whalers
Bluff Formation at Portland.

Chondrichthyes

Isurus sp.

Carcharodon carcharias Linnaeus, 1758
Carcharodon megalodon Agassiz, 1835
Myliobatis sp.

Ischyodus dolloi Leriche, 1902

Mammalia

Marsupialia

?Dasyuromorphia incertae sedis
Diprotodontoidea gen. et sp. undet.
Diprotodontoidea gen. et sp. undet. C
Diprotodontidae gen. et sp. undet. A
Zygomaturinae gen. et sp. undet. T
Palorchestes sp.

Vombatidae gen. et sp. undet.

Sthenurus sp.

Protemnodon sp.

Macropus sp.

Macropodidae gen. et sp. undet. C
Ektopodontidae gen. et sp. undet.

Rodentia

Rodentia incertae sedis
Carnivora

?Phocidae gen. et sp. indet.

Cetacea

Balaenidae gen. et sp. indet.

Balaenopteridae gen. et sp. indet.
cf. Physeter sp.

Kogiidae gen. et sp. indet.

Delphinoidea incertae sedis
cf. Tursiops sp.

Delphinus sp. or Stenella sp.

Delphinidae gen. et sp. undet. A

Materials and methods

All fossil specimens were collected by Mr Sean Wright of Portland and
are in the Palaeontology Collections of Museum Victoria. Anatomical
terminology for periotic s and tympanies follows Evans (1993),
Fordyce (1994), Fordyce and others (2002) and Kasuya (1973) with
mi nor modifications. All periotic and tympanic measurements follow
the methods and dimensions outlined by Kasuya (1973) and were made
using vernier callipers. Photographs were taken using a 35 mm Nikon
Nikkormat EL SLR with a 105 mm macro-lens, and a Nikon D70
digital SLR with a 60 mm macro-lens. Where indicated, specimens
were coated with a sublimate of ammonium chloride to enhance
contrast in black and white (denoted by AC in figure captions). Where
necessary, fragile specimens were consolidated with a hardener con-
sisting of 3% solution of Paraloid B72 (ethyl methacrylate/methyl
acrylate copolymer) in acetone.

Institutional abbreviations. NMV C, Museum Victoria Comparative
Anatomy Collection, Melbourne; NMV P, Museum Victoria
Palaeontology Collection, Melbourne; CD, Phylum Chordata cata-
logue, New Zealand Geological Survey, Lower Hutt; USNM, National
Museum of Natural History (formerly United States National
Museum), Smithsonian Institution, Washington, DC. For a complete
list of specimens referred to in this study, see table 1.

Geology and age of the Whalers Bluff Formation

For about 4 km along cliffs north of Portland Harbour the
Pliocene Whalers Bluff Formation is exposed (Singleton et al.,
1976). This formation is about 7.6 m thick, being comprised of
horizontally bedded fossiliferous clay, oyster-rich beds and
sandy limestones (Abele et al., 1988). These sediments uncon-
formably overlie the Upper Miocene Port Campbell Limestone
and infill a karst topography developed in the top of the
Miocene limestone (Boutakoff and Sprigg, 1953; Dickinson et
al., 2002). The Whalers Bluff Formation is unconformably
capped by basalts.

The age of the Whalers Bluff Formation is well constrained
relative to some other Neogene marine mammal-bearing units
in the SW Pacific (Fig. 2). However, the determination of the
younger age limit of the Whalers Bluff Formation has proved
problematic. The Port Campbell Limestone which underlies the
Whalers Bluff Formation is Late Miocene (indicated by pres-
ence of Globorotalia miotumida\ planktonic foraminiferal
zones N16-basal N17; Tortonian; 8-10.8 Ma) (Dickinson et al.,
2002). Deposition of the Whalers Bluff Formation began
during planktonic foraminiferal zone N19 (indicated by the
presence of Globorotalia puncticulata at the base of the for-
mation) and ensued into the base of planktonic foraminiferal
zone N21 (Fig. 2) (Singleton et al., 1976; Dickinson et al.,
2002). K-Ar dates of 2.5 1 Ma from basalts that cap the Whalers
Bluff Formation have been reported (Singleton et al., 1976).

Beu and Darragh (2001) have suggested that the Whalers
Bluff Formation is latest Pliocene to earliest Pleistocene
(>1.5-2.0 Ma) based on the presence of the pectinid bivalve
Pecten fumatus Reeve, 1852 in a section along the Glenelg
River. However, Pecten fumatus does not occur in the Whalers
Bluff Formation at Portland (Darragh in Singleton et al., 1976;
T.A. Darragh, pers. comm.). Zenatiopsis ultima Darragh and
Kendrick, 1971 occurs in the Whalers Bluff Formation at
Portland but is a Pliocene species and never occurs with

70

Erich M.G. Fitzgerald

Table 1. Specimens referred to in this study. For more detailed locality/stratigraphic data see Fitzgerald (2004b). Abbreviations: e=Early;
m=Middle; l=Late; M=Miocene; P=Pliocene; Pt=Pleistocene; R=Recent; Vic. = Victoria; Tas. = Tasmania; NZ = New Zealand.

Specimen

Taxon

Locality

Lormation

Age

NMV P221242

hums sp.

Portland, Vic.

Whalers Bluff

P

NMV P218415

Carcharodon megalodon

Portland, Vic.

Whalers Bluff

P

NMV P218418

Carcharodon carcharias

Portland, Vic.

Whalers Bluff

P

NMV P218470

Myliobatis sp.

Portland, Vic.

Whalers Bluff

P

NMV P2 18296

Ischyodus dolloi

Portland, Vic.

Whalers Bluff

P

NMV P221241

?Dasyuromorphia gen. et sp. undet.

Portland, Vic.

Whalers Bluff

P

NMV P2 18500

Diprotodontoidea gen. et sp. undet.

Portland, Vic.

Whalers Bluff

P

NMV P2 18498

Diprotodontoidea gen. et sp. undet. C

Portland, Vic.

Whalers Bluff

P

NMV P21 8499

Diprotodontidae gen. et sp. undet. A

Portland, Vic.

Whalers Bluff

P

NMV P221230

Zygomaturinae gen. et sp. undet. T

Portland, Vic.

Whalers Bluff

P

NMV P22 1231

Palorchestes sp.

Portland, Vic.

Whalers Bluff

P

NMV P221238

Vombatidae gen. et sp. undet.

Portland, Vic.

Whalers Bluff

P

NMV P221232

Protemnodon sp.

Portland, Vic.

Whalers Bluff

P

NMV P221235

Macropus sp.

Portland, Vic.

Whalers Bluff

P

NMV P221227

IMacropus sp.

Portland, Vic.

Whalers Bluff

P

NMV P221237

Sthenurus sp.

Portland, Vic.

Whalers Bluff

P

NMV P221229

Macropodidae gen. et sp. undet. C

Portland, Vic.

Whalers Bluff

P

NMV P197795

Ektopodontidae gen. et sp. undet.

Portland, Vic.

Whalers Bluff

P

NMV P221240

Rodentia indet.

Portland, Vic.

Whalers Bluff

P

NMV P2 18273

?Phocidae gen. et sp. indet.

Portland, Vic.

Whalers Bluff

P

NMV P21 8465

?Phocidae gen. et sp. indet.

Portland, Vic.

Whalers Bluff

P

NMV P2 18269

Balaenidae gen. et sp. indet.

Portland, Vic.

Whalers Bluff

P

NMV P2 18268

Balaenopteridae gen. et sp. indet.

Portland, Vic.

Whalers Bluff

P

NMV P2 18298

cf. Physeter sp.

Portland, Vic.

Whalers Bluff

P

NMV P21 8407

Kogiidae gen. et sp. indet.

Portland, Vic.

Whalers Bluff

P

NMV P21 8283

Delphinoidea incertae sedis

Portland, Vic.

Whalers Bluff

P

NMV P2 18284

Delphinoidea incertae sedis

Portland, Vic.

Whalers Bluff

P

NMV P2 18286

Delphinoidea incertae sedis

Portland, Vic.

Whalers Bluff

P

NMV P2 18266

cf. Tursiops sp.

Portland, Vic.

Whalers Bluff

P

NMV P2 18265

Delphinus or Stenella sp.

Portland, Vic.

Whalers Bluff

P

NMV P218264

Delphinidae gen. et sp. undet. A

Portland, Vic.

Whalers Bluff

P

NMV P16198

?Phocidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

lM-eP

NMV P41759

Phocidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

lM-eP

NMV P42523

?Phocidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

eP

NMV PI 60399

Phocidae gen. et sp. undet.

Beaumaris, Vic.

Black Rock Sandstone

eP

NMV PI 60433

Phocidae gen. et sp. undet.

Beaumaris, Vic.

Black Rock Sandstone

eP

NMV PI 60441

Phocidae gen. et sp. undet.

Grange Burn, Vic.

Grange Bum

eP

NMV P215759

?Phocidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

eP

NMV P16195

Balaenidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

eP

NMV P48865

Balaenidae gen. et sp. indet.

Grange Burn, Vic.

Grange Bum

eP

NMV PI 6043 8

Balaenidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

lM-eP

NMV PI 97824

Balaenidae gen. et sp. indet.

Beaumaris, Vic.

Black Rock Sandstone

lM-eP

NMV P171503

Balaenoptera edeni or B. brydei

Tidal River, Vic.

N/A

R

NMV P179005

Megaptera sp.

Lakes Entrance, Vic.

Jemmys Point

eP

NMV P23961

IMesoplodon sp.

Cameron Inlet, Tas.

Cameron Inlet

P

NMV P13033

“Stem” cudmorei

Beaumaris, Vic.

Black Rock Sandstone

lM-eP

NMV P204352

Delphinidae gen. et sp. undet. A

Henley, England

Red Crag

P-Pt

NMV P2 18481

Delphinidae gen. et sp. undet. A

Henley, England

Red Crag

P-Pt

NMV C24972

Kogia breviceps

Cape Conran, Vic.

N/A

R

NMV C24976

Kogia breviceps

Shelley Beach, Vic.

N/A

R

NMV C27879

Eubalaena australis

Altona Bay, Vic.

N/A

R

NMV C28892

Megaptera novaeangliae

Venus Bay, Vic.

N/A

R

CD 53

Delphinidae gen. et sp. undet. A

Chatham Island, NZ

Unnamed

TP

USNM 22953

Orycterocetus crocodilinus

Calvert County, USA

Calvert

mM

USNM 183007

Physeteridae gen. et sp. undet.

Lee Creek Mine, USA

Yorktown

eP

USNM 452993

Scaphokogia cochlearis

Aguada de Lomas, Peru

Pisco

1M

USNM 183008

Kogiidae gen. et sp. undet.

Lee Creek Mine, USA

Yorktown

eP

USNM 251118

Kogiidae gen. et sp. undet.

Lee Creek Mine, USA

Yorktown

eP

Pliocene marine mammals

71

Figure 2. Stratigraphic correlation of the Portland fossil marine mammal-bearing formations with selected major late Neogene marine mammal-
bearing units. Stratigraphy and geochronology are from Bames (1973, 1977, 1984, 1998), Muizon and DeVries (1985), Muizon and Bellon (1986),
Gottfried et al. (1994), Whitmore (1994), Prothero (1998), Fordyce (2002a), Fordyce et al. (2002), Fitzgerald (2004b), Muizon et al. (2004),
Bames et al. (2005) and Gradstein et al. (2004). Abbreviations: AGL, Pisco Formation, Aguada de Lomas level; BL, Batesford Limestone; BRS,
Black Rock Sandstone; CLB, Pisco Formation, Cerro la Bruja; ELJ, Pisco Formation, El Jahuay level; GBF, Grange Bum Formation; LAF,
Lower Member, Almejas Formation; MTM, Pisco Formation, Montemar level; SAO, Pisco Formation, Sacaco level; SAS, Pisco Formation, Sud-
Sacaco level; SDF, San Diego Formation; UAF, Upper Member, Almejas Formation; WBF, Whalers Bluff Formation.

P. fumatus, the latter first appearing at the base of the
Pleistocene (T.A. Darragh, pers. comm.).

These data indicate that the Whalers Bluff Formation at
Portland is Early to Late Pliocene (Zanclean to Piacenzian;
>2.5-4. 8 Ma). Further study of terrestrial mammals from the
Whalers Bluff Formation may help refine the geological age of
this unit. Unfortunately, the exact bed from which fossil verte-
brates were collected within the Whalers Bluff Formation is
unknown. Thus, a finer age resolution than that given above for
the assemblage is currently unavailable. The age range of the
Whalers Bluff Formation presented herein is considered to
be the best estimate based on available data and the reader must
be cautioned that future work may yield a younger limit on the
minimum age.

The Whalers Bluff Formation (as well as, in part, laterally
equivalent Victorian marine mammal-bearing units such as the
Grange Burn Formation, Black Rock Sandstone and Jemmys
Point Formation) has been interpreted as representing a
prograding quartz-carbonate barrier system with the elastic-
dominated units listed above representing an initial marine
incursion (Dickinson et al., 2002: 290).

Systematics of marine mammals
Order Cetacea Brisson, 1762
Suborder Mysticeti Flower, 1864
Family Balaenidae Gray, 1821

Genus and species indeterminate

Referred specimen. NMV P2 18269, incomplete right periotic; anterior
and superior processes virtually complete, but pars cochlearis almost
entirely worn off, and only anteriormost base of posterior process
preserved (Fig. 3A).

Description. P2 18269 is highly polished and abraded. The
anterior process is blunt and globose, being indistinct from the
superior process. There is marked lateral exostosis of the super-
ior process lateral to the epitympanic recess. The lateral aspect
of the anterior process is rugose and pitted. Posteriorly, this pit-
ting decreases in density. Only the lateralmost region of the
pars cochlearis is preserved. In medial view, the most notable
feature is the sulcus for the facial nerve (cr. VII), the course of
cr. VII being preserved from its entry into the body of the
periotic at the aperure of the internal facial foramen, to its
ventral exit into the epitympanic cavity via the ventral facial
foramen. All other features of the pars cochlearis and epitym-
panic recess have been obliterated. Posterior to the broad and
shallow hiatus epitympanicus is a remnant of the base of the
posterior process (which is directed posterolaterally and
somewhat ventrally).

Discussion. Miller (1924: 8-9) listed the following features that
distinguish the periotics of Balaenidae from those of
Balaenopteridae (and other baleen-bearing Mysticeti): (1) axis
of anterior process of periotic parallel with axis of internal
acoustic meatus; (2) [longitudinal] axes of anterior and posteri-
or processes converge at an acute angle; and (3) pars cochlearis
small relative to rest of periotic. In addition to the preceding
features, the possession of massive lateral exostosis of the
anterior process and anterolateral superior process, such that
the anterior process appears swollen (as noted by Fordyce,
1982: 48), seems to be a feature shared by all extant and late
Neogene balaenid periotics. It is largely on the basis of the
latter character and the phenetic similarity of P2 18269 to a
periotic (PI 6 195) from the Lower Pliocene Black Rock
Sandstone of Beaumaris identified as belonging to cf.
“ Balaena ” (Gill, 1957) that P2 18269 is referred to Balaenidae,
genus and species indeterminate.

72

Erich M.G. Fitzgerald

The fossil record of Balaenidae begins in the Late Oligocene
(c. 28 Ma: Fordyce, 2002b), although the record only becomes
reasonably well known from the Mio-Pliocene boundary
onwards (McLeod et al., 1993; Bisconti, 2003). Morenocetus
parvus Cabrera, 1926 is the geologically oldest named
balaenid, from the early Early Miocene (Aquitanian) of
Patagonia. From the end Aquitanian to early Tortonian of the
Miocene the evolutionary history of Balaenidae is virtually
unknown. The extant balaenids include Balaena mysticetus
Linnaeus, 1758, Eubalaena australis Desmoulins, 1822,
E. glacialis Muller, 1776, and E. japonica Lacepede, 1818
(e.g., Cummings, 1985; Reeves and Leatherwood, 1985;
Bannister, 2002). Note that Rice (1998) included all extant
balaenids in the genus Balaena and recognised only two
species, B. mysticetus and B. glacialis. The taxonomic scheme
of Bannister (2002) is used herein. Balaena is known from the
Early Pliocene of the North Atlantic (McLeod et al., 1993;
Westgate and Whitmore, 2002). There are very few confirmed
pre-Quatemary fossil records of Eubalaena. Bisconti (2003,
2005) referred the Pliocene Balaena belgica Abel, 1941 to
Eubalaena belgica. McLeod and others (1993: 63) suggested
that a balaenid periotic from the Early Pliocene of South
Australia (originally recorded by Howchin: 1919) could repre-
sent Eubalaena (as opposed to its original referral to Balaena).
Dixon (1990) described an incomplete Recent Eubalaena
australis skeleton from Altona Bay, near Melbourne, Victoria.
The latter specimen (C27879) includes tympanies and perio-
tics. The extinct genera Balaenula and Balaenotus have been
recorded from the Late Miocene through Pliocene of the N
Pacific (Barnes, 1977; McLeod et al., 1993) and N Atlantic
(McLeod et al., 1993; Bisconti, 2003 and references therein).
Recently, Bisconti (2005) described a new genus and species of
relatively small balaenid, Balaenella brachyrhynus, from the
Early Pliocene of Belgium.

The incompleteness of P2 18269 and lack of information on
the extent of intraspecific and ontogenetic variation in balaenid
periotics, hampers comparisons with described extant and
fossil balaenid taxa. Furthermore, there are as yet no published
criteria for discriminating between the periotics of Balaena and
Eubalaena. Despite these problems, it may be noted that
P2 18269 is similar in overall size to several isolated balaenid
periotics from the uppermost Miocene to Lower Pliocene Black
Rock Sandstone and Grange Burn Formation of Victoria (e.g.
P16195, P48865, P160438, and P197824). The discovery of a
more complete periotic (including the pars cochlearis) is neces-
sary before any further comparisons between the Portland
Pliocene balaenid and the other Victorian specimens listed
above can be made.

Family Balaenopteridae Gray, 1864
Genus and species indeterminate

Referred specimen. NMV P2 18268, incomplete right periotic; lacking
medial three-quarters of pars cochlearis and posterior process
(Fig. 3B).

Description. P2 18268 is polished, rolled and may be secondar-
ily phosphatised. The anterior process is elongated and some-

what attenuated anteriorly. The dorsal surface of the anterior
process is smooth, with only slight rugosity, as seen in the
periotics of extant Balaenopteridae. An oblique groove on the
dorsolateral surface of the anterior process near its preserved
apex is interpreted as a trace of a vascular sulcus. The latter
feature has previously been considered a sulcus for the cap-
suloparietal emissary vein (Geisler and Luo, 1998; Geisler and
Sanders, 2003) or as a sulcus marking the path of an artery,
specifically part of the middle meningeal artery (Fordyce,
1994). Fordyce (1994) and Watson and Fordyce (1994)
described this feature as the anteroextemal sulcus whereas
Geisler and Sanders (2003) treated the anteroextemal sulcus
and sulcus for the capsuloparietal emissary vein as separate fea-
tures. Further work is required to better establish the
venous/arterial correlate of this osteological feature which in
this study is referred to as the sulcus for the capsuloparietal
emissary vein. In extant balaenopterids, this sulcus usually
courses posteriorly to a point level with the position of the
mallear fossa. However, in P2 18268 any more posterior con-
tinuation of the sulcus for the capsuloparietal emissary vein, if
formerly present, no longer occurs due to abrasion.

The ventral presentation of the periotic exhibits several
features. As occurs in extant Balaenoptera and Megaptera, the
lateralmost eminence of the ventrolateral ridge of the superior
process (sensu Geisler and Luo, 1996) is situated at the same
level as the anterior margin of the pars cochlearis. The mallear
fossa is poorly differentiated from the rest of the epitympanic
recess.

The preserved posterolateral margin of the periotic is
formed by the hiatus epitympanicus. The course of the facial
nerve on the ventral surface of the periotic is marked by the
facial sulcus which is bounded anteriorly by the aperture of the
ventral facial foramen. In ventral view, a distinct bridge of
bone at the anterolateral comer of the preserved pars cochlearis
represents the ventral roof of the ventral facial foramen. The
endocranial aspect of the pars cochlearis preserves the aperture
of the internal facial foramen. Anterior to this aperture is a deep
excavation in the medial surface of the periotic at the base of
the anterior process. This region (composed of cancellous bone
in extant balaenopterids) marks the site of ankylosis between
the anterior process and the body of the periotic. As in other
Balaenopteridae, the pars cochlearis appears to have been
elongated towards the cranial cavity.

Discussion. That P2 18268 is a balaenopterid periotic is evident
by the possession of: (1) elongated, triangular and anteriorly
attenuated anterior process; (2) a triangular lateral eminence of
the ventrolateral ridge; and (3) a relatively large pars cochlearis
elongated towards the cranial cavity. Because P2 18268 is rep-
resented only by an incomplete periotic, it is not possible for it
to be identified below family level. The size of P2 18268 is
comparable to that of periotics of subadult Balaenoptera edeni
Anderson, 1879 or B. brydei Olsen, 1913 (P171503) and juve-
nile Megaptera novaeangliae Borowski, 1781 (C28892).
However, the periotics of extant Megaptera novaeangliae and
an undescribed species of Megaptera from the Early Pliocene
of Victoria (PI 79005) possess the following features which
differentiate them from P2 18268: (1) the anterior process is

Pliocene marine mammals

73

Figure 3. Mysticeti and Physeteridae from the Pliocene Whalers Bluff Formation, Portland. A, Balaenidae gen. et sp. indet., incomplete right peri-
otic, NMV P2 18269, in ventrolateral view (AC); B, Balaenopteridae gen. et sp. indet., incomplete right periotic, NMV P2 18268, in ventral view
(AC); C, cf. Physeter sp., apical crown of tooth, NMV P218298, in side view (AC). Scale bars equal 10 mm.

74

Erich M.G. Fitzgerald

relatively shorter; (2) anterior process is more dorsoventrally
compressed; (3) in endocranial view, there is an anteroposter-
iorly thickened region of cancellous bone in the pars cochlearis
anterior to the internal facial foramen; and (4) no deep excava-
tion in the endocranial surface of the periotic anterior to the
pars cochlearis. Many of these features may be related to onto-
genetic variation. At least, the lack of these four features in
P2 18268 may indicate that this periotic is not referrable to
Megaptera and may belong to an indeterminate species in the
genus Balaenoptera.

Suborder Odontoceti Flower, 1867
Family Physeteridae Gray, 1821
cf. Physeter sp. Linnaeus, 1758

Referred specimen. NMY P2 18298, isolated, worn-down apical
region of tooth crown (Fig. 3C).

Description. P2 18298 has an ovoid cross-section at its base
which becomes more ellipsoid towards the preserved apex of
the crown. In occlusal view, the apex of the tooth crown is
incised by a deep anteroposterior cleft which is attributed to
tooth wear. Shallow longitudinal grooves in the surface occur
on all faces of the crown. The basal end of the tooth is broken
to reveal a cross-section through the crown. The only notable
feature of this aspect of the tooth is the presence of thick layers
of cementum.

Discussion. The large size of this tooth and the thick layers
of cementum suggest that P2 18298 represents a physeterid.
Little more can be said about the systematic s of this speci-
men although its size and similarity to teeth of large adult
Physeter macrocephalus suggest affinities with the extant
sperm whale.

Family Kogiidae Gill, 1871
Genus and species indeterminate

Referred specimen. NMV P218407, incomplete left tympanic bulla
(Fig. 4A-B).

Description. The most striking aspect of the morphology of
P2 18407 is its small size. The tympanic is polished with rolled
edges being rounded off. The preserved portion includes only
the medial half of the bulla with very little of the outer lip pres-
ent. The base of the posterior process of the tympanic has been
worn off. In dorsal and ventral view, there is a distinct furrow
in the medial edge of the involucrum between the inner poster-
ior prominence and the inner anterior prominence. In ventral
view, the furrow between the prominences of the involucrum
forms an obtuse angle. There is no preserved ventral keel and
the median furrow is very shallow such that it is poorly differ-
entiated from the surrounding ventral surface of the tympanic.
The interprominential notch is relatively broad. The anterior
edge of the involucrum and outer lip is squared-off. In dor-
sal view, the involucrum has a consistent width along its
length, but is expanded at the level of the inner posterior
prominence.

Discussion. P2 18407 is referred to the Kogiidae on the basis of
the following features shared with extant and fossil kogiids: (1)
small overall size [as Kasuya (1973: 25) noted among extant
Odontoceti only Pontoporia blainvillei Gervais and d’Orbigny,
1844 has a smaller tympanic, and P2 18407 does not resemble
the tympanic of that taxon]; (2) distinct embayment in
the medial edge of the involucrum between the inner anterior
and posterior prominences; and (3) squared-off anterior edge
of the involucrum and outer lip. It should be noted that the
second feature is also seen in the tympanic bullae of
Physeter macrocephalus Linnaeus, 1758, Orycterocetus croco-
dilinus Cope, 1868 (USNM 22953) (Kellogg, 1965)
(Fig. 5C-D), and an Early Pliocene physeterid (USNM
183007) (Fig. 5A, B). Despite this similarity between P2 18407
and the tympanies of Physeteridae, the relatively large size of
physeterid tympanies precludes P2 18407 from being con-
sidered as a physeterid. Furthermore, the inner posterior
prominence in physeterid tympanies is generally more pointed
in outline than the rounded outer posterior prominences in
kogiid tympanies.

Among fossil Kogiidae, the tympanies of Praekogia
cedrosensis (Barnes, 1973b) have not been described. A skull of
Scaphokogia cochlearis Muizon, 1988 (USNM 452993)
includes an associated incomplete left tympanic (Fig. 4E, F).
The tympanic of S. cochlearis is similar to the tympanies of
extant Kogia in its relatively small size and possession of a dis-
tinct embayment in the medial side of the involucrum between
the inner anterior and posterior prominences. The most notable
difference between the tympanic of S. cochlearis and the
Portland kogiid tympanic lies in the more marked inflation of
the inner posterior prominence of P2 18407. S. cochlearis pos-
sesses a less expanded inner posterior prominence, such that
the embayment in the medial face of the involucrum is not as
deep as in P2 18407. In this respect, Scaphokogia cochlearis is
similar to two undescribed Early Pliocene kogiids from the Lee
Creek Mine, North Carolina (USNM 183008, Fig. 4G-H;
USNM 251118, Fig. 4C, D) and the extant Kogia breviceps
Blainville, 1838 (Fig. 41, J).

The features which Kasuya (1973) used to differentiate
between Recent Kogia breviceps and K. sima Owen, 1866 are
not preserved in P2 18407. However, comparison between fig-
ures of the tympanic of K. sima (Kasuya, 1973: plate VIII), and
actual specimens of K. breviceps (C24972, C24976), indicate
that P2 18407 differs from both extant Kogia species in: (1)
embayment in medial edge of involucrum between the inner
prominences is markedly deeper; and (2) the involucrum is less
dorsoventrally and mediolaterally inflated. Despite these dif-
ferences, P2 18407 is almost identical in size to the tympanies
of Kogia breviceps. Given that the currently available evidence
is meagre, P2 18407 is not identified below family level. Table
2 compares some dimensions of the tympanies of kogiids and
physeterids discussed above.

P2 18407 is the first fossil record of Kogiidae from
Australia. Fossil kogiids have previously been reported in the
SW Pacific region, from the ?Late Miocene of the Chatham
Rise, east of New Zealand (Fordyce, 1984a) but that record has
a poorly constrained age (Fordyce, 1989, 1991b).

Pliocene marine mammals

75

Table 2. Measurements of tympanies of Physeteridae and Kogiidae. Measurements follow methodology of Kasuya (1973). All measurements are
in mm.

NMV

C24972

NMV
P2 18407

USNM

22953

USNM

183007

USNM

452993

USNM

183008

USNM

251118

Standard length of tympanic bulla, distance from
anterior tip to posterior end of outer posterior
prominence

26.0

31.0

42

29.0

31

Distance from anterior tip to posterior end of inner
posterior prominence

19.9

21.6

27.0

38

28

31.0

28

Distance from posteroventral tip of outer posterior
prominence to tip of sigmoid process

21.28

_

_

_

_

_

_

Distance from posteroventral tip of outer posterior
prominence to tip of conical process

15.3

_

_

_

_

_

_

Width of tympanic bulla at the level of the sigmoid
process

26.0

_

_

_

_

_

_

Height of tympanic bulla, from tip of sigmoid process
to ventral keel

26.5

Width across inner and outer posterior prominences

19.0

-

20.2

24

22.5

20+

Superfamily Delphinoidea Gray, 1821
Incertae sedis

Referred specimens. NMV P218283, P218284 and P218286, all isolat-
ed teeth (not figured).

Description. P21283, P218284 and P218286 all represent small
odontocete teeth possessing conical enamel-covered crowns
that bear fine wrinkling ornamentation, and curve lingually
towards the crown apex. As in kentriodontids, there is a lingual
bulge at the base of the crown but this feature is not as promi-
nent in the teeth from Portland. None possesses an open pulp
cavity suggesting that all were derived from adult individuals.

P2 18283 is an incomplete tooth, its preserved maximum
length and maximum width of the crown being 16 mm and 6
mm respectively. Due to the incomplete nature of this tooth it
does not warrant further description.

P2 18284 is the most highly polished and the most complete.
It differs from the others in having a mediolaterally compressed
root with a more prominent mesial-distal bulge at its midpoint.
The preserved apex of the root curves posteriorly.

The most notable feature of P2 18286 distinguishing it from
the other teeth is its bulbous root, which contrasts with the
transversely flattened morphology of P2 18284.

Discussion. Only one delphinoid odontocete has previously
been described from the Tertiary of Australia, the latest
Miocene-earliest Pliocene “ Steno ” cudmorei Chapman (1917)
from the Black Rock Sandstone of Beaumaris, Victoria
(Fitzgerald, 2004b). Fordyce (1982) questioned the taxonomic
identity of “5?’ cudmorei (the holotype, P13033, being an iso-
lated tooth) and Fitzgerald (2004b) referred “S.” cudmorei to
Delphinidae, genus and species indeterminate. Chapman
(1917) assigned P13033 to Steno on the basis of the resem-
blance of its crown ornamentation to that seen in the teeth of
the extant Steno bredanensis Cuvier in Lesson, 1828 (e.g.,
Miyazaki and Perrin, 1994). Given that Steno is probably in a
basal position in the phylogeny of Delphinidae (Miyazaki and

Perrin, 1994; LeDuc et al., 1999) and that some of the pre-
sumed ancestors of Delphinidae, the Kentriodontidae (Barnes,
1978, 2002; LeDuc, 2002), possessed Steno-like crown orna-
mentation (e.g., Kellogg, 1966), the anastomosing striae on the
crown of P13033 (and P218283, P218284, P218286) are of
dubious use in assessing the phylogenetic affinities of isolated
teeth. Furthermore, non-delphinid small odontocetes such as
Lipotes vexillifer Miller, 1918 possess anastomosing wrinkling
on tooth crown enamel (Miller, 1918; Brownell and Herald,
1972; Barnes, 1985) which casts doubt on any perceived
taxonomic or phylogenetic signal present in these teeth.

The isolated teeth from Portland are assigned to
Delphinoidea incertae sedis. None of the Portland Pliocene
teeth share demonstrably close affinities with the holotype
tooth of “ Steno ” cudmorei.

Family Delphinidae Gray, 1821
cf. Tursiops sp. Gervais, 1855 sp.

Referred specimen. NMV P2 18266, virtually complete right periotic
(Fig. 6).

Description. P2 18266 is typically delphinid in possessing: (1)
posterior process of the periotic projects laterally and postero-
laterally; (2) longitudinal grooves on the articular facet of the
posterior process of the tympanic (this feature also occurs in
Monodontidae); (3) relatively low crista transversa; (4) internal
facial foramen opens at the same level as the tractus spiralis
foraminosus in the internal acoustic meatus; (5) a short, blunt,
rectangular anterior process of the periotic which in anterior,
dorsal and ventral views appears laterally compressed; (6) a
large fovea epitubaria for the accessory ossicle eliminates the
anterior bullar facet on the anterior process; (7) prominent
parabullary ridge; (8) inflated pars cochlearis; and (9) rela-
tively shallow internal acoustic meatus (Kasuya, 1973; Fordyce
et al., 2002). The first character is usually only seen in
Delphinidae but several taxa in the extinct delphinoid grade-

76

Erich M.G. Fitzgerald

A B

Figure 4. Miocene to Recent Kogiidae tympanies. A-B, Kogiidae gen. et sp. indet. (Pliocene Whalers Bluff Formation, Portland, Victoria,
Australia), incomplete left tympanic, NMV P2 18407 (AC). C-D, Kogiidae gen. et sp. undet. (Lower Pliocene Yorktown Formation, Lee Creek
Mine, North Carolina, U.S.A.), incomplete left tympanic, USNM 251118. E-F, Scaphokogia cochlearis (Upper Miocene Pisco Formation, Aguada
de Lomas level, Arequipa Department, Peru), incomplete left tympanic, USNM 452993. G-H, Kogiidae gen. et sp. undet. (Lower Pliocene
Yorktown Formation, Lee Creek Mine, North Carolina, U.S.A.), incomplete right tympanic, USNM 183008. 1-J, Kogia breviceps (Recent, Shelley
Beach, Victoria, Australia), incomplete left tympanic, NMV C24976. A, C, E, G, I, all in dorsal view. B, D, F, H, J, all in ventral view. Scale
bars equal 10 mm.

Pliocene marine mammals

77

C D

Figure 5. Miocene to Pliocene Physeteridae tympanies. A-B, Physeteridae gen. et sp. undet. (Lower Pliocene Yorktown Formation, Lee Creek
Mine, North Carolina, U.S.A.), right tympanic, USNM 183007. C-D, Orycterocetus crocodilinus (Middle Miocene Calvert Formation, Zone 14,
south of Randle Cliff Beach, Calvert County, Maryland, U.S.A.), right tympanic, USNM 22953. A and C in dorsal view. B and D in ventral view.
Scale bars equal 10 mm.

taxon Kentriodontidae possess a posterolaterally projecting
posterior process of the periotic (eg., Barnes and Mitchell,
1984; Dawson, 1996) as does Albireo whistleri (Albireonidae)
(Barnes, 1984). P218266 and the other odontocete periotics
described below possess all of the characters listed above,
justifying their assignment to Delphinidae. Table 3 presents
comparative measurements of selected dimensions for all
delphinid periotics described herein.

Discussion. Within Delphinidae, P218266 is most similar to
Tursiops and Lissodelphis. P2 18266 is similar to the periotics
of Tursiops in: (1) its overall size; (2) having the aperture of the
internal acoustic meatus opening at the same level as the
endocranial surface of the body of the periotic; (3) having a
deep internal facial foramen; and (4) having an aquaeductus
vestibuli located at the same level as the foramen for the
vestibular branch of the vestibulocochlear nerve. P2 18266

78

Erich M.G. Fitzgerald

Table 3. Measurements of delphinid periotics from the Whalers Bluff Formation and delphinid periotics from the Red Crag, England.
Measurements follow methodology of Kasuya (1973). All measurements are in mm.

NMV

NMV

NMV

NMV

NMV

P218264

P2 18265

P2 18266

P204352

P218481

Standard length of periotic, from tip of anterior process to posterior end of
posterior process, measured on a straight line parallel with cerebral border

28.00

26.66

32.50

29.94

29.40

Thickness of superior process at the level of upper tympanic aperture
Width of periotic across pars cochlearis and superior process, at the level of

11.00

10.00

11.90

12.14

11.58

upper tympanic aperture

Least distance between the margins of fundus of internal acoustic meatus

20.00

17.76

23.00

20.00

19.58

and of aperture of aquaeductus vestibuli

Least distance between the margins of fundus of internal acoustic meatus

2.56

2.16

1.58

3.00

2.50

and of aperture of aquaeductus cochleae

3.00

3.00

3.14

1.50

2.20

Length of the posterior bullar facet

11.00

11.00

11.00

12.46

12.62

Antero-posterior diameter of pars cochlearis

17.00

16.00

17.80

14.66

16.16

differs from Tursiops in: (1) the possession of a more acute
angle between the anterior process and pars cochlearis;
(2) having an aquaeductus cochleae positioned further from the
fenestra cochleae, and further dorsally on the endocranial
side of the pars cochlearis; (3) having a lower crista transversa;
(4) having a poorly developed septum between the tractus
spiralis foraminosus and the foramen for the vestibular branch
of the vestibulocochlear nerve; and (5) having a less rounded
pars cochlearis.

P2 18266 shares with the periotic of Lissodelphis : (1)
endocranial surface of the periotic bordering the posterior
margin of the internal acoustic meatus, aperture of aquaeductus
vestibuli, and aquaeductus cochleae, is uniformly flat; and
(2) aperture of the aquaeductus cochleae opens on the same
plane as the aperture of the internal acoustic meatus (note that
this condition is also seen in Steno). P2 18266 differs from the
periotic of Lissodelphis by: (1) being markedly larger in over-
all size; and (2) having a mediolaterally broader aperture of the
internal acoustic meatus.

The balance of features noted above indicates that P2 18266
is a delphinid with close affinities to Tursiops. This periotic is
not identified as undoubtedly as such due to the subtle differ-
ences between P2 18266 and the periotic of extant Tursiops spp.
Barnes (1990) provided a thorough review of the fossil record
of Tursiops. He recognised four fossil species of Tursiops-. T.
cortesii Sacco, 1891 (Italy; Late Pliocene, c. 1.75-3.5 Ma, and
possibly Early Pliocene, c. 5 Ma); T. astensis Sacco, 1891(Italy;
early Late Pliocene, c. 3-3.5 Ma); T. capellinii del Prato, 1898
(Italy; middle Pliocene, c. 3.5 Ma); T. ossenae Simonelli, 1911
(Italy; middle Pleistocene or late Pleistocene, c. 0.5-0. 8 Ma).
Other unnamed pre-Pleistocene records of Tursiops include:
aff. Tursiops from the Purisima Formation, California (Late
Pliocene, 1.8-3 Ma) (Barnes, 1977); and Tursiops sp. from the
Yorktown Formation, North Carolina (Early Pliocene, 3. 5-4.5
Ma) (Whitmore, 1994).

The record from the Pliocene of Victoria is the first prob-
able pre-Pleistocene fossil record of Tursiops from the
Southwest Pacific. Furthermore, this fossil occurrence provides
corroboration for Barnes’ (1990: 18) hypothesis that Tursiops
has been as geographically widespread during the last six
million years as it is at the present time.

Delphinus sp. Linnaeus, 1758 or Stenella sp. Gray, 1866

Referred specimen. NMV P2 18265, virtually complete left periotic
(Fig. 7).

Description. P2 18265 is smaller than P2 18266 (cf. Tursiops
sp.) (Fig. 6), closely matching the periotics of both Delphinus
and Stenella in overall proportions. Morphological similarities
between P2 18265 and Delphinus include: (1) relatively large
diameter of the aperture of the fenestra cochleae; and (2) aper-
ture of the aquaeductus vestibuli is ellipsoid to slit-like in out-
line and opens posteriorly. However, P2 18265 differs from
Delphinus in: (1) the suprameatal area of the periotic, lateral to
the aperture of the internal acoustic meatus, is less planar and
more convex; (2) the lateral wall of the internal acoustic
meatus lacks an elevated platform which obscures the vesti-
bular foramen in endocranial view; (3) the crista transversa is
lower; and (4) the aperture of the internal facial foramen is
narrower.

Discussion. Whitmore (1994) noted that it is very difficult to
distinguish between Delphinus and Stenella on the basis of
periotic morphology. Confounding generic identification of
P21265 is the fact that the periotics of Stenella show wide indi-
vidual variation (Kasuya, 1973). In both Delphinus and
Stenella, the aquaeductus cochleae opens at a similar position
on the posterior wall of the pars cochlearis. Most preserved fea-
tures indicate closer affinities with Stenella than Delphinus.
However, all of the identified differences between P2 18265 and
Delphinus are subtle, representing differences in degree rather
than kind. I do not advocate the definitive placement of
P2 18265 within either Delphinus or Stenella. In any event, the
somewhat intermediate morphology of P2 18265 between the
periotics of Delphinus and Stenella may indicate that P2 18265
is from an extinct genus closely related to both of the extant
genera in question. In either case, P2 18265 is the first record of
a periotic of the Delphinus-Stenella type recorded from the
Neogene of Australia.

Fossils representing Delphinus or Stenella have been
recorded from: Upper Member Almejas Formation, Baja
California Sur (latest Miocene to Early Pliocene, 3.5-6 Ma)
(Barnes, 1998); San Mateo Formation, California (Late

Pliocene marine mammals

79

Figure 6. cf. Tursiops sp. (Pliocene Whalers Bluff Formation, Portland, Victoria, Australia), right periotic, NMV P218266 (AC). A, ventral view.
B, cranial view. C, medial view. D, lateral view. Scale bar equals 10 mm.

80

Erich M.G. Fitzgerald

Figure 7. Delphinus sp. or Stenella sp. (Pliocene Whalers Bluff Formation, Portland, Victoria, Australia), left periotic, NMV P2 18265 (AC). A,
ventral view. B, cranial view. C, medial view. D, lateral view. Scale bar equals 10 mm.

Pliocene marine mammals

81

Miocene to Early Pliocene, 5-9 Ma) (Barnes et al., 1981);
unnamed blue clays at Waihi Beach, Hawera, New Zealand
(Early Pliocene, 3-3.6 Ma; Beu, 1995) (McKee and Fordyce,
1987; Fordyce, 1991a: 1262); Yorktown Formation, North
Carolina (Early Pliocene, 4.5 Ma) (Whitmore, 1994); Salada
Formation, Baja California Sur (Early to Late Pliocene, 3-5
Ma) (Barnes, 1998); Tirabuzon Formation, Baja California Sur
(middle Pliocene, 3-4 Ma) (Barnes, 1998); SAO Level of the
Pisco Formation, Peru (late Early to early Late Pliocene,
3. 0-4.0 Ma) (Muizon and DeVries, 1985; Muizon and
Domning, 2002); and San Diego Formation, California (Late
Pliocene, 1.8-3.4 Ma) (Barnes, 1973, 1977, 1998).

Genus and species undetermined A

Referred specimen. NMV P2 18264, virtually complete right periotic
(Fig. 8).

Description. P2 18264 differs from all previously described
delphinid periotics from the Pliocene of Portland in its relative-
ly good state of preservation, indicating less post-mortem trans-
port and abrasion, with fine surface details intact. P2 18264 is
distinct from P2 18265 and P2 18266 but intermediate in overall
size. Notable differences between P2 18264 and P2 18265 and
P2 18266 include: (1) a mediolaterally thickened periotic body
lateral to the pars cochlearis; (2) apex of anterior process with
distinct tubercle; (3) possession of two deep creases in the
anteromedial face of the anterior process; (4) aperture of the
internal acoustic meatus is mediolaterally compressed, such
that in endocranial view the meatus is more ellipsoidal and slit-
like in outline than that of either or the others; (5) the aperture
of the internal facial foramen is narrow; and (6) the aperture of
the aquaeductus vestibuli is so narrow that it appears closed.

Discussion. P2 18264 does not closely resemble the periotics of
any Recent delphinids in the Museum Victoria collections, nor
any of the Recent delphinid periotics figured by Kasuya (1973).
However, P2 18264 (Fig. 8) closely resembles two fossil del-
phinid periotics from the Plio-Pleistocene Red Crag of England
(P204352, P2 18481: Fig. 9). Both periotics were originally
identified as Globicephalus uncidens Lankester, 1864 (sensu
Lydekker, 1887) by persons unknown. The Globicephalus
uncidens periotic figured by Lydekker (1887: plate II fig. 11)
probably represents a Globicephala periotic, Globicephalus
being a junior synonym of Globicephala. However, P204352
and P2 18481 (Fig. 9) do not represent Globicephala periotics.

An incomplete delphinid periotic (CD 53) has been
described from late Neogene sediments of uncertain age on
Chatham Island, east of New Zealand (Fordyce and Campbell,
1990). The following features of CD 53 are shared with
P2 18264: well-developed, laterally expanded, parabullary
ridge with a globose, tubercle-like anterior apex; anteroventral
angle is rounded off; creases in ventrolateral parabullary ridge;
and short, broad, fan-like posterior process with heavily fis-
sured posterior bullar facet. Based on these similarities, it is
hypothesised that CD 53 is in the same genus, at least, as
P2 18264. Given the Pliocene age of P2 18264, and Plio-
Pleistocene age of P204352 and P2 18481, this taxonomic
assignment of CD 53 suggests a lowest Opoitian (Early
Pliocene) or younger age for the Chatham Island delphinid

periotic and its host sediments. Fordyce and Campbell
(1990: 62-63) suggested a Late Miocene or younger age for
CD 53. Pending the discovery of more complete cranial
material including periotics of this type, P2 18264 is referred
to an undetermined genus and species of Delphinidae (as are
P204352, P218481 and provisionally CD 53).

Order Carnivora Bowdich, 1821
Suborder Pinnipedia Illiger, 1811
Family ?Phocidae Gray, 1821

Genus and species indeterminate

Referred specimens. NMV P2 18465, incomplete left horizontal ramus
of mandible (Fig. 10). NMV P2 18273, isolated upper incisor or canine
tooth (not figured).

Description. P2 18465 is an incomplete left horizontal ramus
with a preserved length of 69 mm, depth at level of dorsal con-
cavity of 21 mm, and mediolateral thickness at level of poster-
ior alveolus for ml of 10 mm. The surface detail of P218465 is
well preserved relative to most of the other marine vertebrate
fossils recovered from the Whalers Bluff Formation. P2 18465
lacks all of the horizontal ramus anterior to the anterior alveo-
lus for p4 and all of the ascending and horizontal rami poster-
ior to the anteriormost corner of the fossa for m. masseter pars
profundus. No teeth are preserved in situ in the mandible. In
overall proportions, the ramus is lightly built. In posterior and
dorsal view, slight medial inflection of the ramus is visible. In
lateral aspect, there is a small mental foramen located ventral to
the position of the interalveolar septum between the anterior
and posterior alveoli of p4 (Fig. 10B). This position is almost
identical to that of the posteriormost mental foramen on a
mandible referred to Piscophoca sp. by Walsh and Naish
(2002). Such small mental foramina are also present on the
mandibles of Zalophus californianus Lesson, 1828 (Howell,
1929; pers. obs.). Immediately posterior to the posterior
alveolus of ml is a prominent dorsal concavity 25 mm long
(measured from the ml alveolus to the anterior margin of the
fossa for m. masseter pars profundus). This dorsal concavity
resembles that of Piscophoca. The preserved anterior region of
the fossa for m. masseter pars profundus differs from that
of Piscophoca in being dorsoventrally broader with a more
rounded outline.

P2 18273 represents an isolated incisor or canine tooth, 28
mm long; its mesiodistal width at a level just below the base of
the crown is 8 mm while its buccolingual width at the same
level is 6 mm. The crown has smooth enamel and is recurved
towards the apex. The root has a consistent thickness and is
buccolingually compressed.

Discussion. The pinniped fossils recovered from the Whalers
Bluff Formation do not include elements preserving unequivo-
cal synapomorphies of suprageneric pinniped taxa. Berta
(1991) and Berta and Wyss (1994) listed the possession of a
bony flange below the angular process of the mandible as an
unequivocal synapomorphy of Superfamily Phocoidea (sensu
Wyss and Flynn, 1993) but the posterior region of the mandible
is not preserved in P2 18465. However, P2 18465 is tentatively

82

Erich M.G. Fitzgerald

Figure 8. Delphinidae gen. et sp. undet. A (Pliocene Whalers Bluff Formation, Portland, Victoria, Australia), right periotic, NMV P2 18264 (AC).
A, ventral view. B, cranial view. C, medial view. D, lateral view. Scale bar equals 10 mm.

Pliocene marine mammals

83

Figure 9. Delphinidae gen. et sp. undet. A (Pleistocene-Pliocene Red Crag, Henley, England), right periotic, NMV P2 18481 (AC). A, ventral view.
B, cranial view. C, medial view. D, lateral view. Scale bar equals 10 mm.

84

Erich M.G. Fitzgerald

Figure 10. ?Phocidae gen. et sp. indet. (Pliocene Whalers Bluff Formation, Portland, Victoria, Australia), incomplete left mandible, NMV P2 18465
(AC). A, dorsal view. B, lateral view. C, medial view. Black arrow in B points to mental foramen. Scale bar equals 10 mm

referred to the Phocidae on the basis of its morphology and pro-
portions being most similar to the mandibles of phocid seals, as
opposed to otariids and odobenids. It remains possible that
P2 18465 represents an otariid mandible. If this were the case,
then a major rethinking of otariid evolutionary biogeography
would be necessary, as current estimates place the otariid
dispersal into the Southern Hemisphere at around the
Pliocene/Pleistocene boundary (Demere et al., 2003; contra
Repenning and Tedford, 1977, who indicated a latest Miocene
dispersal event at the earliest), and the age of P2 18465 (and
P2 18273) probably predates that horizon.

Given that P2 18465 is not similar in morphology to
Otariidae but shares certain features with some phocids (see
description and discussion below), there is no firm evidence to
suggest that the Portland mandible represents an otariid. The
fact that phocid seal fossils have previously been reported from
Pliocene-aged sediments in Victoria (Fordyce and Flannery,
1983) whereas otariids have not lends further support to the
assignment of P2 18465 to the Phocidae. However, P2 18465
and P2 18273 are not referred unquestionably to Phocidae
because the late Neogene fossil record of marine mammals in
the SW Pacific remains too poorly documented to provide any
absolute idea of the composition of the marine mammal fauna
during the Pliocene.

Among extant and fossil phocid mandibles, P2 18465 is

most similar to those of the Pliocene taxa Acrophoca lon-
girostris Muizon, 1981, Homiphoca capensis Hendey and
Repenning, 1972, and Piscophoca pacifica Muizon, 1981.
P2 18465 may be clearly distinguished from Acrophoca, as it
lacks the wide diastema between cheek teeth characteristic of
Acrophoca (Muizon, 1981). The Portland mandible can be fur-
ther distinguished from Homiphoca (Hendey and Repenning,
1972; Muizon and Hendey, 1980) by the possession of a
well-developed dorsal concavity posterior to ml. P2 18465 is
generally very similar to the mandible of Piscophoca (Muizon,
1981) in its overall proportions, relative length of the dorsal
concavity posterior to ml, subequal diameters of the alveoli
and relatively closely spaced alveoli along the tooth row.
However, it is not possible at this stage to determine whether
the Portland mandible belongs to a species of Piscophoca
or not.

The Australian fossil record of pinnipeds is currently poor.
Fordyce (1991b) summarised the state of knowledge at the
beginning of the 1990s, and virtually nothing has been added
since that time. The oldest fossil pinnipeds from the SW Pacific
are latest Miocene (c. 6 Ma) at the earliest and are from
Australia (Fitzgerald, 2004b). Fordyce and Flannery (1983)
provided a preliminary assessment of these fragmentary fossils
suggesting that they represented monachine phocids. The fos-
sils represent one ?incisor tooth (P16198), two right temporals

Pliocene marine mammals

85

(P160399 and P160441), two fused sacral vertebrae (P41759)
and an articulated series of eight thoracic vertebrae with five
ribs (P160433). None of these specimens has yet been
described and only one of the temporals (PI 60399) has
been figured (Fordyce and Flannery, 1983: 99). Recently, two
other pre-Pleistocene ?phocid fossils have been discovered:
P42523, isolated right metatarsal V; and P2 15759, isolated left
metatarsal V. Both P42523 and P215759 were derived from
beds immediately overlying a phosphatic nodule horizon at the
base of the Black Rock Sandstone (Beaumaris, Victoria), and
are thus early Early Pliocene in age. The exact relationships of
the phocids represented by temporals to extant Monachinae and
their fossil sister-taxa ( Acrophoca , Homiphoca and Pisco -
phoca) have yet to be determined. The report herein of two
probable phocid pinniped fossils from Portland brings the number
of known Australian pre-Pleistocene pinniped specimens to nine.

Conclusions

The fossil marine mammal assemblage from the Pliocene-aged
Whalers Bluff Formation is the first to be described in detail
from Australia. All marine mammal taxa represent members of
extant families and for the most part extant genera: Physeter,
Tursiops , and Delphinus or Stenella. Other taxa, of uncertain
affinities below family level, include a balaenid, balaenopterid,
a third undetermined genus of delphinid and a phocid pinniped.
The diversity of marine mammals in the Portland Pliocene
assemblage is impoverished relative to extant faunas, with at
least 18 marine mammal species regularly occurring in north-
west Bass Strait (Wameke in Menkhorst, 1995; pers. obs.).

Published details of other SW Pacific Pliocene marine mam-
mal assemblages are scanty (Fordyce, 1991a, 1991b;
Fitzgerald, 2004b). Only three Australian assemblages provide
a reasonable basis for comparison with the Portland Pliocene
assemblage; the Beaumaris Local Fauna (Victoria), Grange
Burn assemblage (Victoria) and Cameron Inlet assemblage
(Flinders Island, Bass Strait). However, only the Cameron Inlet
assemblage is approximately contemporaneous with the
Portland Pliocene assemblage (about 2. 5-4. 8 Ma), the
Cameron Inlet Formation being late Early to Late Pliocene
(about 2.0-4.0 Ma; Fitzgerald, 2004b and references therein).
The Beaumaris Local Fauna spans the Miocene-Pliocene
boundary, with an age range for the Black Rock Sandstone of
about 4.5-5. 8 Ma (Dickinson et al., 2002; Wallace et al., 2005).
The Grange Burn assemblage is perhaps slightly younger than
the Beaumaris Local Fauna, with the Grange Burn Formation
being Early Pliocene (>4.35-5.3 Ma) (Dickinson et ah, 2002;
Fitzgerald, 2004; Wallace et ah, 2005). Both the Beaumaris
Local Fauna and the Grange Burn assemblage are (at least in
part) phosphatic nodule bed deposits.

A significant problem in making meaningful comparisons
between the Portland Pliocene assemblage and the other assem-
blages listed above lies in the great disparity in numbers of
specimens collected. Whereas the Portland Pliocene and
Cameron Inlet assemblages are known from 30-40 specimens,
the Beaumaris Local Fauna and Grange Bum assemblage are
known from hundreds of fossils. Nevertheless, with this bias in
mind some preliminary comparisons can be made.

hi all four assemblages almost all marine mammal families
present are extant. The sole exception to this is the occurrence
of the paraphyletic family ‘Cetotheriidae’ (Fordyce and Barnes,
1994; Fordyce, 2003; Geisler and Luo, 1996; Geisler and
Sanders, 2003; Kimura and Ozawa, 2002) in the Beaumaris
Local Fauna and Grange Bum assemblage (Fitzgerald, 2004b).
At the generic level, there appear to be some differences
between the known diversity of marine mammals in the
Portland Pliocene assemblage/Cameron Inlet assemblage and
the Beaumaris Local Fauna/Grange Bum assemblage. In the
latter two, extant genera include cf. Eubalaena, Balaenoptera,
Megaptera, Physeter and cf. Mesoplodon. The delphinids from
the phosphatic nodule bed assemblages do not appear to be
closely related to extant genera, contrary to earlier assessments
(e.g., Chapman, 1917). Rather, delphinid periotics and middle
ear ossicles from the Beaumaris Local Fauna possess a rela-
tively high number of primitive characters with respect to
extant Delphinidae. This is markedly different from the
Portland Pliocene assemblage in which most described del-
phinid periotics seem to represent extant genera. Other appar-
ently archaic aspects of the Beaumaris Local Fauna/Grange
Bum assemblage include the high diversity of physeterid taxa
(three genera, including a small form similar to the form genus
Scaldicetus and another similar to Physeterula dubusii Van
Beneden, 1877) relative to the present (one genus).

The Cameron Inlet assemblage appears to be essentially
modem in aspect based on fossils recovered to date. Fordyce
(1991b: 1183) listed ziphiids (including Mesoplodon sp., based
on isolated periotics), physeterids (cf. Physeter macrocephalus)
and balaenopterids in this assemblage. Fitzgerald (2004: 198)
included cf. Balaenoptera, cf. Megaptera and a possible del-
phinid. Sutherland and Kershaw (1971) reported an incomplete
skull (NMV P23961) as Ziphius sp. but Fordyce (1984b: 939)
later questioned this assignment and re-identified NMV
P23961 as ? Mesoplodon sp. The Cameron Inlet assemblage is
generally similar to the Portland Pliocene assemblage which is
perhaps not unexpected given their similar geological age and
geographic proximity.

It has previously been noted that latest Miocene through
Pliocene marine mammal assemblages across the globe include
extinct, often aberrant, genera and families and formerly wider
(in some cases unexpected) geographic ranges for extant taxa
that today have restricted geographic distributions (Fordyce et
al., 2002 and references therein). Indeed, the apparently recent
evolution of marine mammal faunas of modem aspect led
Fordyce and colleagues (2002) to suggest that among cetaceans
at least a major ecological change occurred about 3-4 million
years ago. This change is marked by the last appearance in the
fossil record of genus and family-level taxa displaying rela-
tively primitive grades of evolution (e.g., Albireonidae,
Herpetocetus : Barnes, 1984; Whitmore, 1994; Oishi and
Hasegawa, 1995; Barnes and Furusawa, 2001; Fordyce and
Muizon, 2001) as well as novel morphological adaptations and
inferred palaeoecology (e.g., Odobenocetopsidae, Austral-
odelphis : Fordyce et al., 2002; Muizon and Domning, 2002).

The early Pliocene is marked by a global warming trend
beginning at c. 4.5-5. 5 Ma with the rapid development of full-
scale Northern Hemisphere and Antarctic glaciation occurring

86

Erich M.G. Fitzgerald

in the late Pliocene at approximately 2.75-3.2 Ma (Zachos et
al., 2001; Ravelo et al., 2004; Wara et al., 2005). Gallagher and
colleagues (2003) presented data indicating that the earlier
Pliocene (3. 1-5.3 Ma) was a time of generally stable marine
temperatures in Bass Strait with surface temperatures per-
haps as much as 3°C warmer than today (Ravelo et al.,
2004). The Late Pliocene in Bass Strait was characterised by a
fluctuating, overall cooler climate than the preceding Early
Pliocene (Gallagher et al., 2003). As Fordyce and colleagues
(2002) have indicated, climatic and oceanic changes associ-
ated with rapid global cooling at c. 3.2 Ma were likely
major influences on the evolution of the modem marine
mammal fauna. A larger sample of marine mammal fossils from
Pliocene-aged assemblages in south-east Australia with finer
resolution of stratigraphic distribution of marine mammal
taxa during the Pliocene is required for more detailed
correlations between Pliocene marine mammal and climatic
evolution.

The description of the Pliocene marine mammal assemblage
from Portland alleviates the dearth of information on SW
Pacific marine mammal assemblages during the late Neogene.
The occurrence of extant cetacean taxa ( Balaenoptera ,
Physeter, Delphinus/Stenella and Tursiops ) in the Whalers
Bluff Formation (>2. 5-4.8 Ma) (and Cameron Inlet Formation)
indicates that the marine mammal fauna off south-east
Australia had begun to take on a modem aspect by at the
earliest 4.8 Ma and latest around 2.5 Ma. Indeed, most of the
cetacean species still exist in the seas off Portland (Wameke in
Menkhorst, 1995; pers. obs.). That the latter cetacean taxa
occur in Early-Late Pliocene deposits in the SW, SE and NE
Pacific, and NW Atlantic, suggests that several extant cetacean
genera were widespread in the world’s ocean basins prior to
about 2.5 Ma.

Acknowledgements

Our rapidly improving knowledge of late Neogene fossil
marine vertebrates off southeast Australia would not be
possible without the collecting efforts of Mr Sean Wright and
his donation of hundreds of fossils to Museum Victoria, for
which he is thanked. The Vertebrate Palaeontology and
Mammalogy departments of Museum Victoria are thanked for
providing research facilities and access to specimens. D.J.
Bohaska is thanked for his assistance with access to specimens
during a visit to the National Museum of Natural History
(Smithsonian Institution) and R. Purdy assisted with photo-
graphic facilities there. The Museum Victoria Library, with the
National Museum of Natural History (Smithsonian Institution)
Remington Kellogg Library for Marine Mammalogy, were crit-
ical in providing access to some otherwise intractable literature.
Dr T.A. Darragh is thanked for discussions on late Neogene
biostratigraphy. This paper was greatly improved by the helpful
review by Ewan Fordyce and editorial comments from Gary
Poore. This work forms part of a Ph.D. thesis undertaken in the
School of Geosciences, Monash University and Museum
Victoria, which was financially supported by an Australian
Postgraduate Award.

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Memoirs of Museum Victoria 62(1): 91-99 (2005)

ISSN 1447-2546 (Print) 1447-2554 (On-line)
http://www.museum.vic.gov.au/memoirs/index.asp

Two new Middle Miocene spatangoids (Echinoidea) from the Murray Basin,
South Australia

Francis C. Holmes 1 , Christopher Ah Yee and Janice Krause 2

‘15 Kenbry Road, Heathmont, Victoria 3135, Australia, and Invertebrate Palaeontology, Museum Victoria, PO Box 666,
Melbourne, Victoria 3001, Australia (fholmes@bigpond.net.au)

2 P.O. Box 581, Hamilton, Victoria 3300, Australia

Abstract Holmes, F.C., Ah Yee, C., and Krause, J. 2005. Two new Middle Miocene spatangoids (Echinoidea) from the Murray

Basin, South Australia. Memoirs of Museum Victoria 62(1): 91-99.

Two new spatangoid taxa are described from the Glenforslan Formation cropping out in the Murray River cliffs near
Blanchetown, South Australia. One taxon, Murraypneustes biannulatus gen. et sp. nov., a large species of spatangoid
with two ‘peripetalous’ fascioles (one circling the margin and the other close to the distal end of the relatively short
petals), two distinct sizes of aboral primary tubercles, and a depressed apical system. The other spatangoid described,
Spatagobrissus dermodyorum sp. nov. differs from the only other fossil species of this genus recorded from Australia,
S. laubei (Duncan, 1877), in having a much shorter labrum, markedly larger peristome and periproct and larger primary
tubercles within the peripetalous fasciole.

Keywords Echinoidea, Spatangoida, Murrraypneustes, Spatagobrissus, new taxa, Middle Miocene, South Australia

Introduction

Of all the Australian Tertiary sedimentary sequences that con-
tain extensive echinoid faunas, the 150 km of Murray River
cliffs, from Overland Comer, east of Waikerie, to Murray
Bridge, South Australia, have over the last 120 years been more
comprehensively studied by palaeontologists, students and
amateur collectors than any other similar area. In the Miocene
stratigraphic sequences along the Murray River and elsewhere
in Australia, species belonging to the Spatangoida constitute
approximately 50 percent of the recorded taxa of irregular
echinoids. In view of the number of spatangoids occurring in
this section of the Murray River cliffs, the discovery in 2003 of
three specimens of a new genus belonging to this order, seem-
ingly unrelated to any other genus known from the continent’s
fossil record, was unexpected.

The specimens were found within 300 m of each other in a
single bed of the Glenforslan Formation, cropping out on the
left bank of the Murray River, 7 km NNE of Blanchetown,
South Australia [Museum Victoria locality PL3203]. Further
investigation of the surface exposure of the formation in the
general vicinity of this discovery failed to produce any
additional specimens of the new genus.

Materials and methods. Specimen numbers prefixed P, on
which the studies are based, are housed in the Invertebrate

Palaeontology collection, Museum Victoria (NMV). In addition
to type material, the new species of Spatagobrissus is repre-
sented by several specimens in private collections. Measure-
ments were made with a dial calliper to an accuracy of 0. 1 mm.
Parameters are expressed as a percentage of test length (%TL)
or test width (%TW).

Age and stratigraphy

The Glenforslan Formation, synonymous with the Lower
Morgan limestone, conformably overlies the Finniss Formation
and is of early Middle Miocene (Batesfordian, Langian) age.
The thickness of the unit is relatively consistent at 13-15 m
although this is reduced in southern exposure due to post-
Middle Miocene uplift and subsequent erosion. The formation
is sublithified to lithified, weathering to whitish-cream colour
in outcrop (Lukasik and James, 1998). It is composed of cycles
of mollusc-bryozoan floatstone, with a microbioclastic pack-
stone matrix, grading upward into Celleporaria rudstone tops
(infaunal bivalve and gastropod-rich microbioclastic matrix
with large branching and sheeted Celleporaria) which also
contain pectens and oysters. Echinoids tend to be found at or
above the rudstone-floatstone contact at the base of the cycles,
the latter containing delicate branching and uni-laminar sheet
bryzoans of 1-3 cm length. Sediments are pervasively mottled,
obscuring all physical sedimentary textures. The middle

92

Francis C. Holmes, Christopher Ah Yee and Janice Krause

Glenforslan Formation is interpreted as being deposited in
relatively shallow waters, possibly less than 10 m, based on the
presence of calcareous algae and mixotrophic foraminifers
(Lakasik, pers. com. 2005). It form s part of the richest warm-
water biotic record from southern Australia at a time of maxi-
mum transgression of the sea across the continental shelf
(McGowran and Li, 1994, and papers cited therein).

The three specimens of the new genus were found about 7.4
m above the base of the formation, approximately 2 m above
the Lepidocyclina Zone.

Associated fauna

Nineteen species of echinoids have been recorded from the
Glenforslan Formation within 500 m upstream and downstream
of PL3203 (Table 1), compared with 28 confirmed species
known to occur within the Morgan Group (Glenforslan, Cadell,
and Bryant Creek Formations).

Table 1. Echinoids recorded within the vicinity of locality PL3203.
Letters in brackets indicate the frequency of occurrence of each
species. [A], abundant; [C], common; [F], fairly common; [U], uncom-
mon; [R], rare. References to authors and supporting literature cited
below, but not listed in the main text references, can be found in
Holmes (1993).

Cidaroida

Goniocidaris murrayensis Chapman and Cudmore, 1934 [C]
Arbacoida

Murray echinus paucituberculatus (Gregory, 1890) [F]
Temnopleuroida

Cryptechinus humilior ( Bittner, 1892) [C]

Ortholophus morganensis Philip, 1969 [C]

O. pulchellus (Bittner, 1892) [C]

Clypeasteroida

Monostychia australis Laube, 1869 [A]

M. sp. ‘C’ in Holmes, 1999 [F]

Scutellinoides patella (Tate, 1891) [C]

Spatangoida

Brissopsis tatei Hall, 1907 [U]

Brissus sp. nov? [R]

Cyclaster archer i (Tenison Woods, 1867) [C]

Eupatagus rotundus Duncan, 1877 [U]

Eupatagus sp. indet. [U]

Hemiaster (Bolbaster) planedeclivis Gregory, 1890 [C]
Lovenia cf. forbesi (Tenison Woods, 1862) [C]
Murraypneustes biannulatus gen. et sp. nov. [R]

Pericosmus compressus (Duncan, 1877) [R]

Protenaster antiaustralis (Tate, 1885) [U]

Spatagobrissus dermodyorum sp. nov [F]

Systematic Palaeontology
Order Spatangoida Claus, 1876
Suborder Micrasterina Fisher, 1966
Family Incertae sedis

Remarks. The combination of generic features, particularly the
presence of a marginal ‘peripetalous’ fasciole, intermittent hor-
izontal fasciole bands and a rudimentary non re-entrant

peripetalous fasciole clear of the distal ends of paired petals,
clearly distinguish the new genus Murraypneustes from virtu-
ally all other taxa assigned to the Micrasterina, in particular the
22 genera included in the Asterostomatidae Fisher, 1966. Only
one of these genera, Asterostoma Agassiz, 1847, has tenta-
tively been retained in the Asterostomatidae (together with
Stomaporus Cotteau, 1888, a genus originally assigned to the
Brissidae Gray, 1855) by Smith et al. (2003). Of the remaining
21 genera, Smith et al. have conditionally reassigned 13 to
other families, only six of which are included in the
Micrasterina. The remaining eight are listed as incertae sedis or
as belonging to an unnamed taxon. Until a detailed revision of
these latter genera is published, it is considered imprudent to
assign the new genus to a specific family.

Murraypneustes gen. nov.

Type and only known species. Murraypneustes biannulatus sp.
nov.

Diagnosis. Large ovoid spatangoid with centrally depressed
adapical surface, apex well posterior of centre. Apical system
ethmolytic with 4 gonopores. Aboral primary tubercles of 2 dis-
tinct sizes, small and randomly spaced, the larger proximal to
the ambitus. Labrum long, narrow, partially tuberculate,
extending to third ambulacral plate. Two ‘peripetalous’
fascioles present; one marginal, passing above the periproct
(pseudolateral); the second, rudimentary, non re-entrant and
clear of the distal ends of paired petals. Intermittent horizontal
fasciole bands also occur between the 2 ‘peripetalous’ fascioles.
Subanal fasciole in contact with marginal periproct.

Etymology. For the Murray River cliffs, the origin of the fossils,
and “pneustes”, a common suffix used for spatangoid
echinoids. Gender masculine.

Remarks. The following analysis of morphological features of
genera similar to Murraypneustes gen. nov. is based primarily
on Mortensen (1950a) and Smith et al. (2003). Although
approximately 30 genera within the Micrasterina have been
investigated, only eight warranted further scrutiny; four cur-
rently unassigned to a family by Smith et al. (2003),
Elipneustes Koehler, 1914, Eurypatagus Mortensen, 1948,
Linopneustes A. Agassiz, 1881, and Platybrissus Grube, 1865;
three belonging to the Maretiidae (Lambert, 1905), Eupatagus
L. Agassiz, 1847, Mazzettia Lambert and Thiery, 1915 and
Spatagobrissus H. L. Clark, 1923; and Macropneustidae genus
Lajanaster Lambert and Sanchez Roig, 1924.

Using a broad comparison of 38 features, Linopneustes
stands out from the other seven genera as having closest affin-
ity with Murraypneustes ; four of its recorded six species,
L. longispinus (A. Agassiz, 1878), L. fragilis (de Meijere,
1903), L. spectabilis (de Meijere, 1903), and L. brachipetalus
Mortensen, 1950b having distinct marginal peripetalous
fascioles passing above the periproct. In the other two,
L. murrayi (A. Agassiz, 1879) and L. excentricus de Meijere,
1903, the peripetalous fasciole is not marginal but somewhat
higher up on the test (Mortensen, 1950a: 221). Although
L. fragilis has multiple fasciole bands around the ambitus,

Two new middle Miocene spatangoids

93

L. murrayi a rounded margin (Smith, pers. com. 2005) and
L. longispinus relatively short closing petals; Murmypneustes
is distinguished by its centrally depressed aboral surface form-
ing four apices (domed on Linopneustes ) with the highest point
of the test posterior to the apical disk (anterior in Linopneustes ),
the presence of two ‘peripetalous’ fascioles and intermittent
horizontal fasciole bands, two distinct sizes of small randomly
spaced aboral primary tubercles, the larger restricted to the
area outside the upper ‘peripetalous’ fasciole, and a prominent
angular subanal fasciole.

Based on the same criteria, three other genera show a mod-
erate degree of morphological similarity to Murraypneustes,
namely Elipneustes, Mazzettia, and Eupatagus.

Elipneustes, however, can be distinguished by its very long,
parallel- sided, open-ended, flush petals with conjugate pore
pairs; single, narrow, marginally situated peripetalous fasciole;
peristome situated immediately below the apical disk; small
thickset plastron with minimal posterior swelling; and much
larger primary tubercles scattered over all the aboral inter-
ambulacra.

Mazzettia, a poorly known fossil genus, has an elongated
heart-shaped test with a low sharp margin, very long weakly-
bowed petals closing distally, no recorded peripetalous fasciole
and only occasionally a weak shield-shaped subanal fasciole,
an elongated labrum just reaching the relatively small plastron,
and random but closely spaced coarse tubercles aborally.

Eupatagus, although possessing well developed peri-
petalous and subanal fascioles is easily categorised by its lack
of an anterior sulcus, predominately short lanceolate closed
petals, primary tubercles of varying density restricted to the
area within the peripetalous fasciole in aboral interlambracra
1-4, and very small evenly spaced tubercles distally over the
remainder of the aboral surface. Comparison of other features
is difficult because of variability among the very large number
of described species. In particular, the eight Australian fossil
species vary considerably in profile, are generally more round-
ed, and have an extremely wide range of primary tubercle
densities when compared with the type species on which the
generic description is based.

Two other genera, Platybrissus and Eurypatagus, are distin-
guished by their complete lack of fascioles, although the former
may have a subanal fasciole present in juvenile specimens.

Lajanaster, although depressed aborally, has no anterior
sulcus, a relatively sharp ambitus, a markedly narrow plaston,
and primary tubercles confined to the posterior column of
anterior and lateral interambulacra within the peripetalous
fasciole.

Spatagobrissus was included in the comparative analysis,
primarily as a new species of the genus occurs at the same
locality (PL3203) as Murraypneustes. In most respects the for-
mer is very similar to Eupatagus but has shorter petals and only
small tubercles over the whole of the aboral surface.

Murraypneustes biannulatus. sp. nov.

Figures 2A-F, 3A-C, 4A, B, 5

Type material. Holotype, NMY P3 12370 from early Middle Miocene
Glenforslan Formation (Batesfordian), Morgan Group, 7 km NNE of

Murray River Lock 1, Blanchetown, South Australia [NMV locality
PL3203].

Paratypes, NMY P3 12371 and P3 12372 from the same location.
Diagnosis. As for genus.

Description. Test moderately large, ovoid in outline with shal-
low anterior sulcus and pointed, slightly truncated posterior.
Specimens range from 72 to 81 mm in length, with maximum
width 81-86%TL occurring at 45%TL from anterior ambitus.
Test 44.1%TL high (uncompressed specimen) with apex of all
specimens well posterior of centre, 63-67%TL from anterior
ambitus.

Centre of test on adapical surface depressed around apical
disk and proximal end of paired petals to form minor apices in
interambulacra 1, 4 and 5, and conjointly, a raised area across
ambulacrum III and interambulcra 2 and 3. Adoral surface
mildly concave in vicinity of peristome with ambulacrum III
slightly recessed anteriorly and the plastron forming a fairly
pronounced keel posteriorly, terminating at the anterior edge of
the subanal fasciole.

Primary tubercles on adapical surface of 2 distinct sizes,
both widely and randomly spaced. Larger of the two restricted
to the distal 35% of the radius on interambulacrum 5, and 25%
elsewhere. Adorally, larger primary tubercles closely and
evenly spaced throughout, with exception of naked areas in
ambulacra I and V and phyllode plates of ambulacra II, III and
IV. Overlapping scrobicules on adoral surface form distinct
diagonal ridges. Small tubercles closely spaced immediately
below ambitus increase in size to that of larger primary
tubercles below curvature of margin. Large primary tubercles,
perforate with undercut mamelon and crenulated platform, and
maximum scrobicular diameter of approximately 2.5 mm,
twice size of smaller counterparts. Ring of scrobicular tubercles
not always present.

‘Peripetalous’ and subanal fascioles present, the former,
though not continuously visible on any specimen clearly
passes above periproct, while latter is distinctly angular, form-
ing hexagonal outline where in contact with lower edge of
periproct. Intermittent horizontal fasciole bands also present
laterally above and parallel to marginal ‘peripetalous’ fasciole.
Uppermost very narrow and more continuous fasciole,
although clear of distal ends of petals, appears to be a rudi-
mentary peripetalus fasciole not indented interradially (Fig. 3).

Apical system anterior of centre, 39.5-42.2%TL from anter-
ior ambitus to centre of disk, level or slightly below proximal
end of paired petals. Ethmolytic, with 4 small closely spaced
gonopores approximately 0.3 mm in diameter, anterior pair
closer together than posterior pair. Detail of ocular plates
indeterminate. Hydropores numerous, approximately 70
visible in one specimen, centrally located but extending
between posterior pair of gonopores and possibly ocular plates
I and V (Fig. 4A, B).

Petals lanceolate, moderately wide at midlength, closed dis-
tally, situated in gentle concave depressions incorporating
adradial edges of adjacent interambulacra and continuing prox-
imally across apical disk. Anterior paired petals shorter than
posterior pair, extending on average 60% of the radius meas-
ured along the surface of the perradial suture from centre of

94

Francis C. Holmes, Christopher Ah Yee and Janice Krause

apical disk to ambitus; posterior pair about 56% radius. Inner
pores of petals oval, outer pores slot-like, slightly curved and
50% wider. Pore pairs not conjugate but linked by a fine ridge
which extends along both sides of each pore (Fig. 5). Maximum
width of interporiferous zone slightly more than twice width of
poriferous zone. Anterior paired petals diverge at approxim-
ately 135° and contain on average 23 pore pairs, posterior
petals 297° and 26 pairs. Secondary tubercles extend randomly
across interporiferous and poriferous zones and for a distance
outside petals without primary tubercles. Ambulacrum III not
petaloid, basically flush with adjoining interambulacra for
about 50% radius, then gradually becoming concave towards
anterior sulcus. Other details unknown, no sign of pores or
regularly spaced tubercles being visible on specimens.

Peristome reniform, centre situated 27-30%TL from
anterior ambitus, longitudinal dimension approximately
6.5%TL, transverse dimension 12%TL. Phyllodes short and not
particularly well developed.

Labrum long and narrow, averaging 20.5%TL, slightly
curved at junction with peristome and abutting the plastron at
centre of third pair of adjacent ambulacral plates. Numerous
small tubercles adjacent to peristome with a few larger ones
towards the posterior end (Fig. 2C).

Plastron closely tuberculate, width approximately 75%
length measured from posterior edge of labrum to anterior edge
of subanal fasciole. Strong posterior taper suggests sixth and
subsequent plates of ambulacra I and V indent behind paired
episternal plates.

Periproct opening marginal, not visible from above, tear
shaped, slightly wider than high, set in a slight truncation
approximately 65° to the horizontal.

Etymology, biannulatus (L) - two-ringed, referring to the pres-
ence of two ‘peripetalous’ fasciole rings.

Family Maretiidae
Spatagobrissus H. L. Clark, 1923

Type species. Spatagobrissus mirabilis H. L. Clark, 1923, by
original designation.

Diagnosis. See H. L. Clark (1923: 402)

Spatagobrissus dermodyorum sp. nov
Figures 6A-E, 7A-C, 8A-E

Type Material. Holotype. NMV P3 12570 from early Middle Miocene
Glenforslan Formation (Batesfordian), Morgan Group, in the vicinity
of NMV locality PL3203, 7 km NNE of Murray River Lock 1,
Blanchetown, South Australia.

Paratypes, NMV P312571-P312373 from the same general area.
Other material used for statistical purposes is held in Museum Victoria
and private collections.

Description. Test small, subcircular in outline with minimal
posterior truncation and no anterior sulcus. Specimens range
30.0-45.5 mm in length with maximum width 82-90%TL
occurring 51-58 %TL from anterior ambitus. Maximum
height 49.5-60%TL at 52.6-65.5%TL from anterior
ambitus. Adapical surface moderately inflated, evenly curved

transversely above well-rounded margin with ambitus situated
at about 30%TH. Adoral surface very mildly convex but with
prominent posterior keel caused by sharp rise of ambulacra I
and V posterior to centre. In lateral view, posterior truncation
covers about 35%TH.

Apical system ethmolytic with 4 genital pores, centre
31.3-38.6%TL from anterior ambitus (Fig. 7A). Paired petals
short (26.5-32.5%TL measured along surface of perradial
suture from centre of apical disk), narrow (7.0-9.0%TL), lance-
olate, closing to closed, posterior pair marginally longer than
anterior pair. Anterior pair diverge at about 135°, posterior pair
310°. Pore pairs conjugate, inner pores oval, outer-tear shaped.
Anterior row of pore pairs in anterior paired petals distinctly
narrower than posterior row and atrophied adapically.
Interporiferous zone up to 1.5 times width of poriferous zone at
widest point. Ambulacrum III flush adapially, with 2 rows of
indistinct longitudinally orientated pore pairs and interporifer-
ous zone containing few secondary tubercles and numerous
miliaries.

Peripetalous fasciole subcircular, not indented. Numerous
small, randomly spaced perforate, crenulate, primary tubercles
occur in interambulacra within fasciole. Outside fasciole,
tubercles in posterior half of test very small, but anterior to
centre, gradually increasing in size towards interambulacra
2 and 3.

Peristome reniform, mildly sunken, width 16.0-19. 3%TL,
length 8.9-10.3%TL with anterior border 23.4-26. 8%TL from
anterior ambitus. Phyllodes moderately developed with slot-
shaped pores in circular depressions. Labrum short and wedge-
shaped extending only to centre of second pair of adjacent
ambulacral plates. Anterior edge raised above surrounding
ambulacra and slightly projecting over peristome. Miliary
tubercles present with few secondary tubercles in anterior half
(Fig. 7B).

Plastron long, width about 55-60% length, with ambulacral
plates indenting posteriorly. Subanal fasciole circular to trans-
versely oval, enclosing 3 pore pairs each side of interradial
suture, and with slight anterior projection at posterior end of
prominent plastronal keel. Posterior edge of fasciole margin-
ally clear of periproct opening. Adorally, ambulacra I and V
relatively wide, covered with very fine, randomly spaced
miliary tubercles up to sixth plate, then by tubercles of similar
size to rest of adoral surface.

Periproct, tear-drop shaped, generally positioned vertically
on truncated posterior margin but slightly visible from
above on some specimens; height 17.1-19.1%TL, width
13.2-16.0%TL.

Etymology. Named for Michael and Marie Dermody, owners of
Glenforslan Station.

Remarks. Spatagobrissus dermodyorum sp. nov. differs pri-
marily from the Middle Miocene Port Campbell Limestone
species, Spatagobrissus laubei (Duncan, 1877), in having
narrower test with more posterior maximum width (Fig. 8A),
markedly larger peristome and periproct (Fig. 8D, E), and very
much shorter labrum (Fig. 8B). In addition, anterior paired
petals are shorter and posterior petals longer (Fig. 8C), with
divergent angle of latter greater than S. laubei. Aboral primary

Two new middle Miocene spatangoids

95

tubercles larger within peripetalous fasciole and interambulacra
2 and 3, while fine tubercles outside fasciole on posterior half
of test are much smaller in diameter. Adorally, plastron wider
and longer, and ambulacra I and V narrower.

The extant type species Spatagobrissus mirabilis is charac-
terised by a larger (up to 110 mm long) and less inflated test,
more posteriorly located apical system in line with maximum
width, greater area enclosed by peripetalous fasciole, shorter
peristome, and periproct situated on an obliquely truncated
surface below the ambitus. Primary tubercles within the
peripetalous fasciole of S. mirabilis are also larger and more
closely spaced than in S. dermodyorum.

Spatagobrissus incus Baker and Rowe, 1990, an extant
species endemic to southeast Australian waters, particularly
between Flinders Island (Tasmania) and western Spencer Gulf,
South Australia, has a larger and more rounded test (up to 80
mm long) and, similar to S. mirabilis, more posteriorly located
apical system and greater area enclosed by peripetalous
fasciole.

Compared with S. dermodyorum, it also has a much
wider and longer plastron and narrower adoral ambulacra
I and V. Miskelly (2002: 156) noted two pairs of pore
pairs occur in each side of the subanal fasciole, a feature also
recorded for S. laubei (McNamara et al., 1986: 80). This
contrasts with the three pairs found on S. dermodyorum
(Fig. 1C).

Discussion

The major diagnostic features of Murraypneustes, particularly
the position of the two ‘peripetalous’ fascioles, the intermittent
horizontal fasciole bands, and the random pattern and separ-
ation of two distinct sizes of primary tubercles across the
aboral surface, give little indication of its lineage. Certainly,
within the Australian Cenozoic sequences that predate the early
Middle Miocene Glenforslan Formation, all the 13 recorded
genera of Micrasterina have their peripetalous fasciole close or
in contact with the paired petals. Only the brissid Cyclaster
is recorded as having developed multiple fascioles in some
specimens (McNamara et al., 1986: 68).

Similarly, there are no extant genera in Australian
waters that have any specific combination of characters that
link them to Murraypneustes. Even the extant species
Linopneustes brachipetalus, found off the east coast of
Australia, has long petals in contact with its marginal
peripetalous fasciole.

The lack of any juvenile specimens of the new genus, or
indeed any marked variation in the size of the three known
specimens, precludes any useful comment on the disposition
and specific function of its somewhat unusual arrangement of
fascioles, as such development takes place at a very early stage
of ontogeny.

Excluding Murraypneustes, only Hemiaster, of the nine
spatangoid genera known to occur in the Glenforslan
Formation sequence which embraces locality PL3203 (Table
1), has no extant record in Australian waters. The eight remain-
ing genera are today almost exclusively benthic filter feeders,
living inshore or on the continental shelf. Five, Brissopsis,

Brissus, Cyclaster, Lovenia and Pericosmus, occur in tropical
waters, and three, Eupatagus, Protenaster and Spatagobrissus
in temperate waters (Rowe and Gates, 1995). Species of these
eight extant genera, with the possible exception of Cyclaster,
are known to occur at depths of less than 20 m in Australian or
New Zealand waters. This depth range is consistent with the
sedimentary deposition of the Glenforslan Formation. On the
other hand, Indo-Pacific species of Linopneustes, including
L. brachypetalus, are found at depths exceeding 270 m (range
272-1788 m), with only the West Indies species, L. longispinus,
extending up into sublitoral waters (70-570 m) (Mortensen,
1950a).

Based on the available evidence, it is reasonable to assume
Murraypneustes dermodyi was a benthic filter feeder inhabiting
relatively shallow, warm (?sub-tropical) waters.

Acknowledgements

We are indebted to David Holloway (Invertebrate Palaeontol-
ogy, Museum Victoria) for valuable advice and support during
the preparation of this manuscript, and to Kenneth McNamara
(Western Australia Museum), Rich Mooi (California Academy
of Sciences) and Andrew Smith (Natural History Museum,
London), for suggesting improvements to the manuscript. Jeff
Lukasik (Petro-Canada) is thanked for providing specific strati-
graphic information and Ashley Miskelly (Blackheath, NSW)
for details of extant echinoids from Australian waters. Michael
and Marie Dermody and Donald and Miriam Griffen
(Blanchetown District, South Australia) are also thanked for
permission to collect on their properties. As always, Val Hogan
and Sandra Winchester (Library, Museum Victoria) were
helpful with access to references.

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157-163.

Rowe, F.W.E., and Gates, J. 1995. Echinodermata. In Wells, A. (ed.).
Zoological Catalogue of Australia , Vol. 33. CSIRO Australia:
Melbourne, xiii + 510 pp.

Smith, A.B., Stockley, B., and Godfrey, D. 2003. Spatangoida. In:
Smith, A.B. (ed.), The echinoid directory. http:Avww.nhm.ac.uk/
palaeontology/echinoids [accessed 19 Jun 2005].

Figure 1. A, B, general location maps; C, map of the Murray River between Waikerie and Swan Reach,
South Australia, showing locality of NMV locality PL3203, north of Blanchetown.

Two new middle Miocene spatangoids

97

Figure 2. Murraypneustes biannulatus gen et sp. nov. A-D, adapical, posterior, adoral and left lateral views of holotype NMV P3 12370;
E, adapical view of paratype NMV P3 12371; F, left lateral view of paratype, NMV P3 12372. All from the early Middle Miocene Glenforslan
Formation in the vicinity of NMV locality PL3203, north of Blanchetown, South Australia.

Figure 3. Fasciole details of Murraypneustes biannulatus gen. et sp. nov. A, B, oblique lateral view and ambulacrum IV detail above margin of
paratype, NMV P3 12371; C, oblique posterior view of paratype, NMV P3 12372. Scale bar 10 mm.

Francis C. Holmes, Christopher Ah Yee and Janice Krause

Figure 4. Apical disk details of Murraypneustes biannulatus gen. et sp.
nov. A, holotype NMV P3 12370; B, drawing of paratype, NMV
P3 12372, showing extent of hydropores (black circles), tubercles
(white circles), and gonopores and oculars (black or stippled).
Location of posterior oculars (marked *) is assumed. Scale bars 1 mm.

Figure 5. Murraypneustes biannulatus gen. et sp. nov. Detail of pore
pairs and tubercles in and adjacent to ambulacrum V of paratype,
NMV P3 12372.

Figure 6. Spatagobrissus dermodyorum sp. nov. A, B, D, adapical, adoral, and left lateral views of holotype, NMV P3 12570; C, adoral view of
paratype, NMV P3 12571; E, posterior view of paratype, NMV P3 12572 All specimens from the early Middle Miocene Glenforslan Formation in
the vicinity of locality NMV PL3203, north of Blanchetown, South Australia. Scale bars 10 mm.

test length {mm)

Two new middle Miocene spatangoids

99

Figure 7. Spatagobrissus dermodyorum sp. nov. A, detail of petals and apical disk of holotype, NMV P3 12570; B, peristome and labrum
tuberculation of paratype, NMV P3 12571; C, subanal fasciole and pore pairs of paratype, NMV P3 12573. Scale bars 1mm.

Figure 8. Comparative biometric data on specimens of Spatagobrissus laubei (Duncan, 1877) from the Middle Miocene Port Campbell Limestone,
Port Campbell, Victoria (•), and S. dermodyorum sp. nov. from the early Middle Miocene Glenforslan Formation, Blanchetown district, South
Australia (o).

Contents

Memoirs of Museum Victoria

Volume 62 Number 1 2005

1 > Homalonotid trilobites from the Silurian and Lower Devonian of south-eastern Australia and
New Zealand (Arthropoda: Trilobita: Homalonotidae)

Andrew C. Sandford

67 > Pliocene marine mammals from the Whalers Bluff Formation of Portland, Victoria, Australia
Erich M.G. Fitzgerald

91 > Two new Middle Miocene spatangoids (Echinoidea) from the Murray Basin, South Australia
Francis C. Holmes, Christopher Ah Yee and Janice Krause

Volume 62 Number 2 2005

103 > The millipede genus Lissodesmus Chamberlin, 1920 (Diplopoda: Polydesmida: Dalodesmidae)
from Tasmania and Victoria, with descriptions of a new genus and 24 new species
Robert Mesibov

147 > A review of pygal-furrowed Synallactidae (Echinodermata: Holothuroidea), with new species
from the Antarctic, Alantic and Pacific oceans
P. Mark O’Loughlin and Cynthia Ahearn

181 > A new asterinid genus from the Indo-West Pacific region, including five new species
(Echinodermata: Asteroidea: Asterinidae)

P. Mark O’Loughlin and Francis W.E. Rowe

191 > A review of soles of the genus Aseraggodes from the South Pacific, with descriptions of
seven new species and a redescription of Synclidopus macleayanus
John E. Randall

213 > The species of Dasycercus Peters, 1875 (Marsupialla: Dasyuridae)

P.A. Woolley